What are the characteristics of Polymer PTFE Capillary Tube?

1.    Main characteristics of Ptfe teflon capillary tube

(1).Very low friction coefficient: its friction coefficient is generally only 0.04, is a very excellent self-lubricating material, and the friction coefficient does not change with the temperature.

(2). High chemical stability: it can withstand all strong acids, including aqua regia, hydrofluoric acid, concentrated hydrochloric acid, nitric acid, fuming sulfuric acid, organic acid, strong alkali, strong oxidant, reducing agent and various organic solvents. Very suitable for high purity chemical feeding.

(3). Good anti - viscosity, tube wall is not easy to adhere to colloid and chemicals.

(4). Excellent electrical insulation performance: PTFE is a highly nonpolar material with good dielectric properties and great resistance. Its dielectric constant is about 2.0, which is the smallest among all electrical insulation products.

(5).Flexible and flexible.

(6).Good anti - viscosity, tube wall is not easy to adhere to colloid and chemicals.

(7).Part of the tube transparency, easy to observe the internal fluid status.

2.  Polymer Ptfe capillary molding process

Ptfe capillary tube is a special pipe made by drying, high temperature sintering and finalizing after mixing ptfe dispersion resin and propellant, and then subjected to certain shearing force in the mouth mold with cone Angle.

Ptfe capillaries are extremely fine, forming a set of independent general specifications according to its use. Also may according to the different need, makes the black capillary tube, the white capillary tube, the yellow capillary tube, the red capillary tube and the transparent capillary tube and so on, generally is blue or the black reel packing.

3. Use of ptfe teflon capillary tube

   It is widely used in chemical industry, chlor-alkali industry, machinery, automobile, electric heating pipe, pulp, steam, compressed gas, heat exchanger, coating, textile, pharmaceutical, medicine, bicycle industry, coffee machine and other industries, mainly used as catheter.

In addition can also use fep (PVF and six f propylene copolymer) made of transparent tube, its basic retain the performance of ptfe, such as: excellent high and low temperature resistance, chemical stability, electrical insulation, prominent not sticky and high mechanical strength, only on the high temperature limit 50 ℃ lower than the ptfe. But it is more flexible and transparent than ptfe, making it easier to see what's going on inside as it transports liquids and gases.

ptfe thin wall tubing Teflon capillaries are made of polytetrafluoroethylene (known as Teflon, commonly known as Teflon, plastic king) materials, and then dried, high-temperature sintering, shaping and other special pipe. Because the tube is generally the size of a blood vessel, it is also known as Teflon capillaries. At present, Teflon capillaries are widely used […]

PTFE Capillary Tubing, PTFE, 2 m x 1.8 mm O.D. x 0.5 mm I.D.

PTFE Capillary TubingPTFE capillary for transformer,HOSE, Teflon capillary, transformer bushings/capillary. Performance:Resistance to acid and alkaliNon-stick (there is no adhesive on the market at present)insulationPolytetrafluoroethylene (PTFE, F4) features pure white appearanceHigh temperature resistance: operating temperature -200 ~ 260℃;Low temperature resistance: 5% at -196℃;Corrosion resistance: strong acid, alkali, aqua regia and various organic solvents;Insulation resistance: dielectric properties are independent of temperature and frequency;High lubrication: the lowest friction coefficient of solid materials;2. Not to adhere to any substance;Non-toxic.

Tubes and pipes in technical and everyday use

In the beginning was the hollowed-out tree trunk, one of the first capillary tube to be crafted by human hand. With a vast array of models in the plant world to inspire him, Homo sapiens had a much easier job inventing the tube than the wheel for which, by contrast, nature had no example to offer. Bamboo and reed are just two examples of plants with hollow stalks. Nature already knew the value of the tubular form, which combines high stability with the capacity to Transport essential substances for growth, such as water and nutrients, out of the earth.

In technical terms, a tube or pipe is a cylindrical, hard hollow body which usually has a round cross-section but can also be oval, square, rectangular or more complex in profile. It is used on the one hand to convey liquid, gas and solid matter and, on the other, as a construction element. Whatever its purpose, the term covers all sizes and diameters, from the smallest needle pipes right up to wind tunnels. No other profile shape with the same material cross-section has such a high flexural strength, which is what makes the tube so important as a load-bearing element in building.

Tubes for transporting purposes

In the past, people always tried to settle close to water. As the size of the settlements grew, it became increasingly difficult to get the water from the source - the spring, pond, river or lake - to the different dwellings. At first, people used open conduits - initially simple trenches, later stone canals. When the springs and sources were exhausted, aqueducts were used to carry water from the mountains into the towns. Some 300 years A.D., the Romans transported water from the Campagna into their capital and some of their impressive waterways can still be marvelled at in modern-day Europe.

Later, the open canals were covered over and used as closed conduits - and thus the pipeline was born. People were also quick to realize the benefits of closed pipes against open canals for removing waste water. Early pipe materials included wood and stoneware (fired clay), but also easy-to-work metals such as bronze, copper and lead. The first closed pipelines were made around 4,000 years ago of fired clay. The oldest metal pipelines date back to 200 years B.C., first made of bronze and later lead. Lead pipes were cast and chiefly used to Transport water. Copper pipes meanwhile were made from chased copper plate which was rolled and subsequently soldered together.

The advent of an economical method of producing large quantities of cast iron in the 14th century laid the foundation for the manufacture of iron pipes. Gunsmiths and cannon-makers were amongst the first to produce iron pipes. Cast iron pipes were used as early as the 15th century to carry water - some dating back to the 16th century are still in use today. Cast iron pipes also accompanied the development of a public gas supply network, for which compression-proof pipes were a matter of safety and therefore absolutely essential.

As more economical steelmaking methods were developed, an opportunity opened up for this material to be used for pipes. The first were forge-welded out of hoop steel, a method already known to gunsmiths in the Middle Ages. Around 1880, the invention of crossrolling by the Mannesmann brothers also made it possible to produce seamless pipes and tubes. With their thicker walls, seamless pipes offered greater stability at a relatively low weight. Oil-prospectors used such pipes to reach deeper reservoirs and by doing so were able to satisfy the growing demand for mineral oil which accompanied the early days of motorisation. The fact that mineral oil could be transported economically over long distances through a pipeline pushed up the demand for steel pipes even further. Soon, pipelines came to be the biggest market in this area, with demand reaching several million tonnes of welded and seamless pipes every year.

The crucial importance of how a pipe is made for the economic efficiency and environment-friendliness of industrial plant can be illustrated with the contemporary example of seamless boiler pipes with inner ribs. For years the power industry has been aiming to reduce fuel consumption and thereby cut CO2 emissions by stepping up efficiency. This can be done by working with higher operating pressures and temperatures. Consequently, plans have been made to set up new power plant in the first decades of the next century, which will run with pressure levels of up to 350 bar (today's maximum is 300 bar), at operating temperatures of around 700 "C (as opposed to 600 'C) and with efficiency increased from fts current 40% to 50%. Operating parameters of this kind can only be used for suitabie products and materials, of which seamless boiler pipes with inner ribs are one example. On account of their internal geometry, these pipes substantially improve the heat transfer between heating and the vapour phase on the inside of the pipe.

Pipes made of nonferrous metals and plastics Thanks to its good corrosion resistance, copper can be used to make pipes for the chemical industry, refrigeration technology and shipbuilding. Alongside their application for installation purposes, the usually seamless copper pipes are also used in capacitors and heat exchangers. For corrosive materials, low temperatures or stringent demands on the purity of the material carried by the pipe, Aluminium and Aluminium alloys are used in pipe construction. Meanwhile, thanks to its high resistance to many aggressive materials, titanium is well- suited to use in chemical engineering.

Plastics belong to the group of newer pipe materials. With the development of methods for producing plastics on an industrial scale in the 1930s, it also became possible to manufacture plastic pipes economically. By the middle of the 30s, plastics were already being used in Germany to make pressure pipelines. Among the chief advantages of plastics are their high corrosion resistance and a substantial chemical resistance to aggressive media. Moreover, the smooth surfaces mean that plastic pipes are not prone to incrustation, which can have a very detrimental effect on their conveying capacity. Pipes supplying drinking water are mostly made of polyethylene (PE) or polyvinyl chloride (PVC). Like ABS (acrylonftrile-butadiene-styrene copolymer) plastics, these two materials are also used for gas pipelines. Thermoplastic materials - alongside PE and PVC these include PP (polypropylene) and PVDF (polyvinylidenefluoride) - can also be used for industrial pipelines. Beyond these, PB (polybutene) and PE-X (cross- linked polyethylene) are also widespread in pipe-making. Plastic pipes find application in areas such as heating technology, shipbuilding, underwater pipelines (the crossing below a river floor from one bank to the other), irrigating and drainage plant, and well-building.

The right choice of material has a crucial bearing on the economic efficiency and safety of a pipe system. Materials therefore have to be selected according to the demands of each specific application. In steel boiler construction, for example, pipes must be made of steel with high temperature stability plus heat and scaling resistance, while special corrosion resistance is all-important in the chemical and foodstuffs industries. Meanwhile, the mineral-oil processing industry requires heat- proof or press-water-resistant steels for its pipes, gas liquefaction and separation, on the other hand, need materials which have special strength at low temperatures. This broad and highly diversified range of requirements has put a fantastic array of materials to use in pipe- making. Alongside the iron and steel, nonferrous metals and plastics mentioned above, these also take in concrete, clay, porcelain, glass and ceramics.

In addition to liquids and gases, solid matter, broken down, as dust or mixed with water in slurry form, is also pumped through pipelines. Gravel, sand or even iron ore can be conveyed in this manner. Pneumatic transportation of grain, dust and chips through pipes is also a widespread practice. Pneumatic tube conveyors, which similarly work with air, are another important mode of transporting solid matter.

Pipes may be several meters in diameter and pipelines many kilometers in length. At the other end of the scale are conduits with tiny, barely perceptible dimensions. One example of their use is as cannulas in medicine - a collective term referring to instruments with a variety of applications, including infusions, injections and transfusions. Their outer diameter ranges from over 5 millimeters to as little as 0.20 millimeters. Cannulas are made of high-quality grades of stainless steel, brass, silver or nickel silver (an alloy of copper, nickel and zinc, sometimes admixed with traces of lead, iron or tin), but also plastics such as polyethylene, polypropylene or Teflon. Often, different materials are combined with one another to produce the individual components. These tiny tubes must have extremely pronounced elastic properties. They may bend but under no circumstances snap. Their surfaces are often nickel[-plated and always highly polished, sometimes even on the inside. The best-known cannulas are hypodermic needles which, in their most common form as sterile disposable syringes, guarantee aseptic use without costly preparation for reutilisation.

Tubes for construction

No matter where we look in our cities today, we can be sure to see tubular steel constructions. They have become an indispensable element of modern building technology. Once again, we took the idea from nature: in tube-shaped straws, bamboo shoots, quills and bones, Mother Nature demonstrated the successful marriage of beauty and function. Yet these excellent static properties remained unexploited until the advent of welding technology made it possible to connect virtually all dimensions of pipes perfectly and with the necessary interaction of forces for use as construction elements.

As an extremely lightweight building element, steel tube combines high strength with low weight. Steel tubes are used as deck supports in shipbuilding, supports in steel superstructures and binders in building construction. They are used as tubular and lattice masts for overhead and overland transmission lines, for trains and trams, and for lighting. Bridges, railings, observation towers, diving platforms, television towers and roof constructions in halls or sports stadiums are all further examples. Steel tube is also a popular" building element for constructions in temporary use, such as halls, sheds, bridges, spectator stands, podiums and other structures for public events, supporting structures and scaffolding, from the small-scale for house renovation right up to building scaffolds.

In plant engineering, steel tube is used to make ladders, shelves, work tables and subframes for machinery and plant. Steel tube also found its way as a construction element into precision components for machinery and equipment. Shafts and rolls or cylinders in hydraulics and pneumatics are just two examples. Beyond these applications, a great volume of steel tube is used in the cycle industry, camping equipment manufacture, the furniture industry, vehicle and car making and the domestic appliances industry.

Be it on water, over land or in the air, the various modes of Transport would be lost without pipes & tubes. Pipes and tubular construction elements are to be found in ships, planes, trains and motor vehicles. A great variety of pipes and tubular profiles are used in car making, both in connection with the motor and with the chassis and bodywork sections. Most recent developments put them to a far more varied range of uses than before, from air suction pipes and exhaust systems through chassis components right up to side-impact tubes in doors and other safety features. One German car makers new lightweight concept takes as its basic subassembly a three-dimensional frame made up of complex Aluminium extruded sections joined together with the aid of pressure-diecast intersections.

Pipes in everyday use

We come into contact with pipes and tubes on a daily basis. It starts in the morning when we go to clean our teeth and squeeze the toothpaste from this tube, which is nothing other than a tube-shaped flexible container. We write notes with a pen, comprising one or more tubes with a smaller tube - the cartridge or refill - inside it. This is the modern equivalent of the quill, a pointed and split tube used in ancient times as a writing instrument and still used today for Arabic script.

We are surrounded everywhere we go and on a virtually constant basis by seamless pipe ＆ tube, whether at home, on the move or at work. They take the form of lamp stands and furniture elements in chairs or shelves, curtain rails, telescopic aerials on portable and car radios, and rods on umbrellas or sunshades. And when we water the plants or hang out the washing, tubes are our constant companion - on the watering can or the clothes-horse. Pipes Transport electricity, water and gas directly into our homes. Tubes protect visitors to the Duesseldorf Trade Fair Center from the rigours of the Rhineland weather. Pipe constructions are responsible for a pleasant indoor temperature and prevent the hall roofs from falling on our heads. Civil engineers and architects choose special section tube constructions for windows and doors in preference to other solutions. Tubes even have a role to play in our leisure time, providing us with bicycles, training apparatus and sports equipment.

Musical pipes

Musical instrument-making would be unthinkable without welded pipe ＆ tube. The tuba illustrates the connection particularly well: the name of this brass instrument is nothing other than the Latin word for tube. Other brass and pipe instruments also take the tube form. The reed used in a variety of wind instruments such as the clarinet, saxophone, bassoon or oboe is a flexible piece of cane which is fixed into the mouthpiece of the instrument or acts as a mouthpiece itself. Organ pipes also rely on the tube shape to create their sound. They are made of lead and tin, zinc or copper and are still crafted today according to a centuries-old Tradition.

CD stands in the shape of organ pipes make for an original link between two musical words. These CD stands are just under two meters in length, accommodate up to 50 CDs and, if required, can be supplied with interior lighting. Normally out of sight but critically important for good sound quality are the bass-reflex pipes found in loudspeakers. With the proper dimensions in length and diameter, these pipes help to reproduce low-pitched tones without any distortion as a result of unwanted flow noise.

Through squre pipe ＆ tube flows the lifeblood of progress and without them our lives would not be nearly as comfortable. They make everyday life easier, safer, more attractive, more varied and more interesting. More to the point, though, they have become indispensable for our existence, shaping the development of our lives to lasting effect in the past and undoubtedly continuing to do so in the future.

Chapter 32: Gas Chromatography

GAS CHROMATOGRAPHY

Is one of most widely used technique in qualitative and quantitative analysis. The components of a vaporized sample are separated by being distributed between a mobile gaseous phase and a liquid or a solid stationary phase held in a column.

2 types of Gas Chromatography

Gas-solid chromatography (GSC)

Gas-liquid chromatography (GLC) 

Gas-solid chromatography

Gas-solid chromatography is based on a solid stationary phase in which retention of analytes occurs because of physical adsorption. It has limited application because of semi-permanent retention of active or polar molecules and severe tailing of elution peaks. Gas-solid chromatography permits the separation and determination of low-molecular-mass gases, such as air components, hydrogen sulfide, carbon monoxide, and nitrogen oxides.

 Gas-liquid chromatography

Gas-liquid chromatography has a widespread use in all fields of science where its name is usually shortened to gas chromatography (GC) and is based on partitioning of the analyte between a gaseous mobile phase and a liquid phase immobilized on the surface of an inert solid packing or on the walls of capillary tubing. 

A flow scheme for gas-liquid chromatography

The method consists of, first, introducing the test mixture or sample into a stream of an inert gas, commonly helium or argon, that acts as carrier. Liquid samples are vaporized before injection into the carrier stream. The gas stream is passed through the packed column, through which the components of the sample move at velocities that are influenced by the degree of interaction of each constituent with the stationary nonvolatile phase. The substances having the greater interaction with the stationary phase are retarded to a greater extent and consequently separate from those with smaller interaction. As the components elute from the column they can be quantified by a detector and/or collected for further analysis.

*to understand it more please watch this.

Instruments of Gas-liquid Chromatography

→  Carrier Gas System

The mobile phase gas in gas chromatography is called the carrier gas and must be chemically inert. Carrier gas must be dry, free of oxygen and chemically inert mobile-phase employed in gas chromatography. Helium is most commonly used because it is safer, has a larger range of flow rates, and is compatible with many detectors.  Nitrogen, argon, and hydrogen are also used depending upon the desired performance and the detector being used.  Both hydrogen and helium provide a shorter analysis time and lower elution temperatures of the sample due to higher flow rates and low molecular weight.All carrier gasses are available in pressurized tanks and pressure regulators, gages and flow meters are used to control the flow rate of the gas. Inlet pressures usually range from 10 to 50 psi (lb/in 2), yielding flow rates of 25 to 150 mL/min with packed columns and 1 to 25 mL/min for open tubular capillary columns.

Classical Soap Bubble Meter

In classical soap-bubble meter, a soap film is formed in the path of the gas when a rubber bulb containing an aqueous solution of soap or detergent is squeezed. The time required for this film to move between two graduations on the buret is measured and converted to volumetric flow rate. Flow meter with digital readouts become common and is located at the end of the column.

→  Sample Injection System

Used to inject liquid samples through a rubber or silicone diaphragm, or septum, into a heated sample port located at the head of the column. The sample usually kept at about 50oC greater than the boiling point of the least volatile component of the sample. A sample port is necessary for introducing the sample at the head of the column.  Modern injection techniques often employ the use of heated sample ports through which the sample can be injected and vaporized in a near simultaneous fashion.  A calibrated micro syringe is used to deliver a sample volume in the range of a few microliters through a rubber septum and into the vaporization chamber. 

→  Gas chromatographs autoinjectors and autosamplers

For the most reproducible sample injection, newer gas chromatographs use autoinjectors and autosamplers. With such autoinjectors, syringes are filled, and the sample injected into the chromatograph automatically. In the autosampler, samples are contained in vials on a sample turntable. The autoinjector syringe picks up the sample through a septum on the vial and injects the sample through a septum on the chromatograph.

For introducing gases, is often used instead of a syringe. Sample sizes can be reproduced to better than 0.5% relative. Liquid samples can also be introduced through a sampling valve.

→  Column Configurations and Column Ovens

Column temperature is an important variable that must be controlled to a few tenths of a degree for precise work. Thus, the column is normally housed in a thermostated oven and are usually formed as coils having diameters of 10 to 30 cm to fit in these varies in length from less than 2 m to 60 m or more. They are constructed of stainless steel, glass, fused silica, or Teflon. The optimum column temperature depends on the boiling point of the sample and the degree of separation required. Roughly, a temperature equal to or slightly above the average boiling point of a sample results in a reasonable elution time (2 to 30 min). For samples with a broad boiling range, it is often desirable to use temperature programming whereby the column temperature is increased either continuously or in steps as the separation proceeds.

The oven temperature was programmed as follows: 185°c in the beginning, maintained for 1 min, increased to 230°c at 5°c/min, maintained for 8 min. coffee oil (A) peaks: 1, palmitic acid methyl ester; 2, stearic acid methyl ester; 3, oleic acid methyl ester; 4, linoleic acid methyl ester; 5, linolenic acid methyl ester; 6, arachidic acid methyl ester; 7, gadoleic acid methyl ester; and 8, behenic acid methyl ester. algae oil (B) peaks: a, myristic acid methyl ester; 1, palmitic acid methyl ester; 3, oleic acid methyl ester; 9, docosapentaenoic acid methyl ester; and 10, docosahexaenoic acid methyl ester. 

Fatty acids in coffee oil (A) and algae oil (B) using a DB-WaX column by modifying temperature programming condition. Note: helium was used as carrier gas

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*CHAPTER 24 IS CONTINUED ON THE NEXT POST