ASME B31.1 Power Piping,ASME B31.3 Process Piping,ASME B31.8 Piping Systems
|Brand Name︰||ASME B31.1,B31.3,B31.8 Pipe Spools,Mechanical Pipe
|Country of Origin︰||-
|We have specialized in offshore Pipe Spool. With high quality, we completed pipe spools for drill ship, FPSO/FPU, Semi RIG & TLP and we are still progressing. Also, we have various and extensive experiences in pressure vessel , steel structure for onshore plant including HRSG.
They prefabricated components of a piping system are called pipe spools. They include the pipes, flanges and fittings, and they are mounted during the fabrication before they are delivered to the construction are. They are delivered pre-mounted so to make them easier to assemble using hoists, gauges, and other tools for assembly. Pipe spools connect long pipes with flanges at the tips so that they can be bolted to another pipe with matching flange. Pipe spools are imbedded into concrete walls before the concrete is poured. The pipe spool has to be positioned properly before concrete is to make sure that it can withstand the weight and force of the concrete as it is poured. This process is important because you will need to go back and run the pipe sometime in the future.
PIPE SPOOLING APPLICATION
The construction of power plants and petroleum refineries requires intensive piping. These industries need to connect a variety of equipment which will be used to carry and transport processed fluid and gas. Because of limitations of space on site and the need to finish the construction fast, these industrial construction projects have no recourse but to rely seriously on fabrication and assembly performed away from the site. This piping process has two stages – pipe spool production and site installation.
PIPE SPOOL FABRICATION
Pipe spools are fabricated using various types of raw pipes and pipe fittings and they include flanges, elbows, tees, and a lot more. They are usually fabricated offsite. The raw pipes are pre-cut to specific sizes and together with pipe fittings and other components. They are temporarily fitted together. This partially finished sub-assembly is then welded with other spool components.
The entire pipe spooling process can be grouped into two:
1. Spool roll fitting and welding
2. Spool permanent position fitting and welding
In spool roll fitting and welding, the main pipe can be turned using a rolling machine and the fitter does not need to alter his position to perform the task. In spool position fitting and welding, a portion or portions of the main pipe go beyond the clearance limit forcing the fitter to move around the main pipe in order to complete the fitting and welding process. That is why spool position fitting and welding is generally a longer process compared to spool roll fitting and welding. Reducing the number of spool position fitting and welding is one of the objectives of pipe spool fabrication sequencing.
Pipe spools are sections of pipe that have been put together with fittings off-site to meet the needs of a construction project, according to the International Journal of Architecture, Engineering and Construction. Pipe spools increase the speed of construction.
Prefabricated pipe spools allow pipe assembly in the early stages of a construction project. Also, pipes are easier to connect inside a climate-controlled facility than at the construction site, and pipe assemblies can be moved around and manipulated while they are being welded together off-site. If they are assembled at the work site, manipulation is usually impossible, and welders need to move into awkward positions to complete their work.
|Specifications︰||Why pipe spools are pre-fabricated?
Shop Pre-Fabrication of pipe spools is a proven means for reducing field installation costs while providing the highest of quality in the products fabricated.
Pipe spools are often flanged to facilitate the connection to other spools. The fabrication of these spools is normally performed by specialist fabrication companies which are equipped with the required infrastructure.
The specialist fabricators work under defined set of quality management criteria to ensure the accuracy of fabrication in order to achieve the roper fit at site and to maintain the required technical parameters defined by the client.
Cost Savings in Pre-Fabrication, Inspection & Testing
Quality of the work is easier to manage & maintain in a controlled environment. High accuracies on specified tolerances will avoid rework at site.
Weather independent fabrication will minimize production delays.
Prefabricated Spools are the perfect answer to severe skill & labor shortage. Users do not have to mobilize significant work force for fabrication of spools on site.
Manufacturing in mass production, will result in lower manufacturing costs compared with site fabrication.
Prefabricated Spools will take lesser fabrication / assembly time, thereby avoiding time & cost overruns.
Prefabricated Spools will entail no or little investments in fabrication & testing equipments by users. Radiography, PMI, MPI, Ultrasonic tests, Hydro tests etc. can be performed better & effectively in controlled environments.
Prefabricated Spools will be serviced under the strict vigilance of Third Party Inspection Agencies, ensuring 100% adherence to required quality standards.
Better control on welding parameters in controlled environments resulting in lesser probability of rework at site.
Weld less Induction Bends (as permitted by the client) would entail complete avoiding of welding pipe sections using SR elbows, thereby bringing in significant cost savings in welding, radiography of welding joints & material requirements.
Lesser dependency on power availability, avoiding unnecessary time delays.
Improved safety in better manufacturing conditions than on site.
Fabricating spools off site means less slag, abrasive dust, smoke & other contaminants which are unacceptable in highly hygienic food processing & other industries.
ASME/ANSI B36.10/B36.19 Carbon, Alloy and Stainless Steel pipe
ASME B31 (B31.1, B31.3) Standards of Pressure Piping
ASME/ANSI B16 Standards of Pipe and Fittings
(A106B/C, A53BC, API5L and X Grade)
(Grades 304, 316, 304H, 347)
(P91, P22, P11, P9, P5)
Speciality and Exotic Alloys
Monel / Inconel / Incoloy / Hastelloy
Alloy 20 / Titanium
METALS INT'L provides sourcing, spool fabrication including induction and cold bending, heat treatment, NDE, hydro testing, blasting, painting, passivation, pickling, packing (crating, bundling and containerizing), and fob/ddu shipment services to its international customers for small and large bore low and high temperature carbon steel, stainless steel, low and high alloy steel piping systems based on manual and automated welding technology utilizing gtaw, saw, stt, smaw, fcaw, gmaw and hotwire for wide range of diameter and wall thicknesses.
MIL supplys critical Piping systems including but not limited to steam, water, oil, gas and air services typically found in electric power generating stations in industrial and institutional plants, geothermal heating systems and central district heating and cooling systems namely boiler piping, boiler external piping, non-boiler external piping, main steam piping, on base and off base auxiliary piping etc. AND
non-critical process piping systems that transport process fluids (e.g. air, steam, water, industrial gases, fuels, chemicals) around an industrial facility involved in a process or for the power and petrochemical industries where ASME stamps or CE marking is required.
|Standard Met︰||Urethane Lined Pipe Piping Spool made of polyurethane elastomer. It has the characteristics of high wear resistance, high strength, light weight and long service life
Urethane Lined Pipe Piping Spool Principle:
Polyurethane Cyclone is a separation and classification equipment.
Based on the principle of centrifugal sedimentation, a strong three dimensional elliptical strongly rotating shear turbulence motion is generated when the two mixed liquids are separated from the Polyurethane Hydro Cyclone into the cyclone at a certain pressure.
Due to the size difference between the coarse particles and fine particles, so the mixed liquid by centrifugal force, centripetal force, drag force etc. in different sizes.
By centrifugal sedimentation, the majority of coarse particles through the Polyurethane Hydrocyclone underflow outlet, while the majority of fine particles from the overflow tube discharge, so as to achieve separation.
Urethane Lined Pipe Piping Spool Characteristic:
♠The high efficiency liquid/liquid hydro cyclone provides maximum oil/water separation efficiency,
♠The solid/liquid hydro cyclone is a cyclone clarifier that offers continuous solids removal from liquid.
♠Both can be used in industrial process water, industrial reuse, oil/water separation, andclarification/separation applications.
♠The liquid/liquid Polyurethane Hydro Cyclones is one of the most advanced, yet least complicated oil/water separation devices available.
♠It effectively removes free oil and grease in a compact package, at a cost far less than other types of separators. Liquid/liquid hydro cyclones are ideal for oily process water andoil-field produced water applications.
♠The solid/liquid Polyurethane Cyclones offers effective solids removal in a compact package.
♠It can handle high levels of solids, with removal capabilities down to five micron.Solid/liquid Polyurethane Cyclones are ideal for treating oily process water and oil-field produced water, desanding of injection water and for sand jetting systems applications.
Urethane Lined Pipe Piping Spool Use:
♣Due to the higher recovery rates of the 10, 12, 15 and 20 inch (250, 305, 380 and 500mm) Classifying Polyurethane Cyclones, an optimum amount of fine particles that are washed will be recovered from a dilute stream and transported to downstream dewatering equipment.
♣Available in 10, 12, 15, and 20-inch (250, 305, 380, 500mm) diameters.
♣Unique lower cone arrangement permits ultra fine separations
♣Ranging from near 60 to 200 mesh and (0.250 to 0.074mm) D95 separation size
Urethane Lined Pipe Piping Spool Solutions:
♠ Polyurethane Wheel Urethane Wheel
♠ Polyurethane Base Urethane Base
♠ Polyurethane Mould Parts Urethane Mould Parts
♠ Polyurethane Plate Urethane Plate
♠ Polyurethane Accessories Urethane Accessories
♠ Polyurethane Block Urethane Block
♠ Polyurethane Pad Urethane Pad
♠ Polyurethane Roller Urethane Roller
♠ Polyurethane Rubber Roll Urethane Rubber Roll
Material Used for Rubber Lining of Piping System
Rubber linings are mainly used for protection against corrosion and/or erosion damage.
A wide range of rubbers and elastomers are available for lining vessels, tanks and piping.
Rubbers can also be made with anti-static properties to give a low surface electrical resistance.
Hard rubbers, i.e. hardness greater than Shore D 60, can only be applied by autoclave vulcanization, and therefore hard rubber lining is restricted to small equipment or components. Only soft rubbers can be applied on site.
Hard rubber linings can only be applied to rigid structures and they are also sensitive to large temperature fluctuations. Soft rubber linings remain elastic over a large temperature range, and consequently they can accommodate major deformation, vibrations and significant temperature changes.
With respect to safety aspects, pressure rating, etc. the regulations which apply to piping, equipment and structures are also valid for rubber-lined systems.
Material selection is determined by:
- service conditions (pressure, temperature, medium, etc.)
- manufacturing method
The following rubber types are used for lining purposes (classification according to ASTM D 1418):
- Isoprene or natural rubber (NR)
- Synthetic isoprene rubber (IR)
- Styrene-butadiene rubber (SBR)
- Chloroprene rubber (CR)
- Butyl rubber (IIR)
- Broom-butyl rubber (BIIR)
- Chloro-butyl rubber (CIIR)
- Nitrile-butadiene rubber (NBR)
- Ethylene propylene rubber (EP, EPDM)
- Urethane rubber (UR)
- Chlorosulphonated polyethylene (CSM)**
- Fluoro elastomer (FKM)*
* Commercially available under trade name "Viton" (DuPont product)
** Commercially available under trade name "Hypalon" (DuPont product)
Depending on the degree of vulcanization, rubbers can be classified as 'soft' rubber or as 'hard' rubber. The hardness of soft rubbers is expressed in Shore A, and the hardness of hard rubbers is expressed in Shore D (ASTM D 2240).
Hard rubbers (or Ebonites), i.e. with a hardness higher than Shore D 60, can be produced from NR or blends, e.g. NR/IR, NR/SBR and NR/IR/SBR.
Properties of Rubber
Each rubber material has a specific limit in terms of allowable service temperature and chemical resistance. The chemical resistance and temperature limits for continuous service of several rubber types are given below.
1. Natural rubber (NR)
Soft and hard natural rubber linings are suitable for handling most inorganic chemicals, with the exception of strong oxidising agents such as chromic and nitric acids. Natural rubber linings are also suitable for handling hydrochloric acid. Natural rubber is also resistant to most organic fluids, including alcohols and most esters. They should not be used in the presence of aliphatic or aromatic hydrocarbons, halogenated hydrocarbons, mineral oils and certain vegetable oils. The allowable service temperature range is -40 °C to +80 °C.
The bond strength of NR linings on steel is excellent. The hardness is typically Shore A 55 for soft rubber and Shore D 75 for hard natural rubber.
2. Synthetic isoprene rubber (IR)
Isoprene rubber is a synthetic alternative form of NR, and has similar properties.
3. Styrene-butadiene rubber (SBR)
Styrene-butadiene rubber can be used for the containment of automotive brake fluids, alcohols and mixtures of alcohol and water. The allowable service temperature range is -30 °C to +80 °C. The hardness is in the same range as that of soft natural rubber (NR).
4. Chloroprene rubber (CR)
Chloroprene rubber is resistant to ozone and sunlight, and reasonably resistant to oils and chlorine. Special compounds are suitable for use with refrigerants (e.g. Freon 12 and 22).
The allowable service temperature range is -30 °C to +105 °C. Hardness is approximately Shore A 60.
5. Butyl rubbers (IIR, BIIR, CIIR)
Butyl rubbers have excellent tolerance to hydrochloric acid. Butyl rubber is resistant to ozone and sunlight, non-flammable hydraulic fluids, animal and vegetable oils, water, alcohols, ketones and acids. Butyl rubber should not be used in the presence of free halogens, petroleum oils or halogenated or aromatic hydrocarbons. The allowable service temperature range is -30 °C to +110 °C. Hardness is in the range of Shore A 55 to A 60.
6. Nitrile butadiene rubber (NBR)
Nitrile butadiene rubber (also known as BuNa-N) is a copolymer of butadiene and acrylonitrile. The acrylonitrile content must be at least 35% by mole to obtain good chemical resistance. Nitrile rubbers are resistant to petroleum-based hydraulic and lubricating oils, animal and vegetable oils, acetylene, alcohols, water, alkalis and fuel oils. Nitrile rubber should not be used for phenols, ketones, acetic acids, most aromatic hydrocarbons and nitrogen derivatives. The allowable service temperature is -35 °C to +80 °C. Hardness is approximately Shore A 60.
7. Ethylene propylene rubbers (EPDM / EPM)
Ethylene propylene rubbers are resistant to ozone and sunlight, oxidizing chemicals, non-flammable hydraulic fluids, pure aniline, fire extinguisher liquids, acids, hot water and steam. However, these rubbers are not resistant to mineral oils, petrol solvents and aromatic hydrocarbons. The allowable service temperature range is -40 °C to +150 °C. Hardness is typically in the range Shore A 40 to A 80.
8. Urethane rubber (UR)
Urethane rubber has excellent wear/erosion resistance and is chemically resistant to mineral oils, fuels and ozone. Urethane rubber should not be used for concentrated acids, ketones or chlorinated hydrocarbons, and shall not be used for water above 50 °C.
Otherwise, the allowable service temperature range is -40 °C to +70 °C. Hardness is typically in the range Shore A 50 to A 80.
9. Chlorosulphonated polyethylene (CSM)
Chlorosulphonated polyethylene is a highly wear-resistant synthetic rubber with excellent resistance to heat, ozone sunlight, oxidising media, sodium hypochlorite and sulphuric acid.
CSM rubber has also good resistance to most oils, lubricants and aliphatic hydrocarbons, but is unsuitable for use with esters and ketones. The allowable service temperature range is -35 °C to +80 °C. Hardness is approximately Shore A 60.
10. Fluoro-elastomers (FKM)
Fluoro-elastomers are copolymers of hexa-fluoro-propylene and vinyldiene fluoride. They are suitable for both high-temperature and vacuum applications. These materials have excellent resistance to oils, fuels, lubricants, carbon tetrachloride, most concentrated acids and many aliphatic and aromatic hydrocarbons such as toluenes, benzene and xylene.
They should not, however, be used with low molecular weight esters and ethers, ketones, certain amines and hot anhydrous hydrofluoric or chlorosulphonic acids. These materials are also resistant to ozone and sunlight and can be used in contact with many corrosive gases, e.g. bromine and chlorine. However, they are not resistant to ammonia or highpressure steam. The allowable service temperature range is -20 °C to +230 °C. Hardness is typically in the range Shore A 60 to A 90.