Modern Periodic Table


Introduction to Modern Periodic Table of Elements:




               


          The periodic table is a tabular display of the chemical elements, organized on the basis of their properties. Elements are presented in increasing atomic numberAtomic number is the number of electrons present in an atom of an element.Atoms of all the elements try to get 8 electrons in their outer most shell (valence shell) of the atom (Octet rule). In doing so, each atom gain or lose /share electrons with the atoms of   other elements resulting in the formation of compounds.The atoms of rare gases or noble gases have their outermost shell (valence shell) completely filled. Hence they do not react

             The main body of the table is a 18 × 7 grid, with gaps included in to keep elements with similar properties together, such as the halogens and the noble gases. These gaps form four distinct rectangular areas or blocks. The f-block is not included in the main table, but rather is usually floated below, as an inline f-block would make the table impractically wide. The periodic table accurately predicts the properties of various elements and the relations between properties.
     



Uses of Modern Periodic Table of Elements:
  • Knowing the atomic number, it is easy to locate and predict the chemical properties of any element in the periodic table.
  • The position of the element in the periodic table will help us to write its electronic configuration and identify the valence electrons in the atom of the element.
  • It reveals the similarities, differences and trends in chemical properties of the elements clearly.
  • One can easily write the molecular formula and predict the compound formed by the given two elements with the help of the periodic table.



Basics of Periodic Table of Classification of Elements

  1. The periodic table of elements consists of horizontal rows called periods and vertical columns called groups.
  2. There are 18 groups and 7 periods in the periodic table.
  3. The elements of group 1 have one valence electron; group 2 elements have 2 valence electrons and so on. Zero group elements have 8 electrons in their outermost shell. Thus the elements of each group have similar properties.
  4. Thus one can identify the valence electrons of the atom of the element from the group it is placed.
  5. Lanthanides and actinides falling under the same group are shown separately below the table.
  6. The elements in I period have their electrons placed in one shell or they have only one main shell.  The elements of the II period have two main shells and so on.
  7. Elements on the left side of the periodic table are called metals. Elements on the right side of the periodic table are occupied by non metals. The metals and non metals are separated by metalloids. One can tell that the metals take most part of the table by glancing at it.
  8. Metallic to non metallic decreases along a period of the periodic table.



Key words: modern periodic table, modern periodic table with names and atomic numbers, periodic table of elements,modern periodic table 2012

Introduction and classification of Gears

Introduction to Gears:



    What is a gear (or) Explain gears?

       Gears are used to transmit motion and power between rotating shafts by means of progressive engagement of projections called teeth.Gears use no intermediate link and transmit motion by direct contact.
          Gears operate in pairs, the smaller of the pair is called the “PINION” and the larger is called the “GEAR” usually, the pinion drives the Gears and when the teeth are meshed, rotation of one shaft and pinion causes the Gear and its shaft to rotate.

Gears can be used to
  • a.     Change the direction
  • b.     Run angular ways
  • c.      Avoid slipping, which is a common phenomenon in belts.

Applications of Gears:

             Now–a–days, Gears are used in most machinery & they range in size from the smallest gear in watch mechanism to bigger(around 100 feet diameter) Gears in radar antennas. In many machines like machine tools, automobiles, tractors,hoisting, mechanisms, rolling mills, marine engines, etc… Gears play a vital role.


Classification of Gears:

          The Gears of toothed wheels may be classified as follows:
According to the position of the shaft axis:
         
a) Parallel shafts
                    1.Spur Gears
                        2.helical Gears
                       3.Herring bone or double helical gears.

b) Intersecting shafts
                   1.Bevel Gears
                             1.1 Straight Bevel Gears
                             1.2 Spiral Bevel Gears
                             1.3 Zero Bevel Gears

c) Non-parallel shafts
                             1.Hypoid Gears
                             2.Crossed Helical Gears
                             3.Worm and Worm wheel 


Explain about Spur Gears and classification of spur gears?

      

What is a SPUR gear (or) Explain Spur gear?      

           Spur gears have straight teeth cut parallel to the rotational axis. The tooth form is based on the involute curve. Practice has shown that this design accommodates mostly rolling, rather than sliding,contact of the tooth surfaces.The involute curve is generated during gear machining processes using gear cutters with straight sides.Near the root of the tooth, however,the tool traces a trochoidal path, providing a heavier, and stronger, root section. Because of this geometry, contact between the teeth occurs mostly as rolling rather than sliding. Since less heat is produced by this rolling action, mechanical efficiency of spur gears is high, often up to99%. Some sliding does occur,however. 
             
              And because contact is simultaneous across the entire width of the meshing teeth, a continuous series of shocks is produced by the gear. These rapid shocks result in some objectionable operating noise and vibration. Moreover, tooth wear results from shock loads at high speeds. 
            
              Noise and wear can be minimized with proper lubrication, which reduces tooth surface contact and engagement shock loads.Spur gears are the least expensive to manufacture and the most commonly used, especially for drives with parallel shafts. The three main classes of spur gears are: external tooth, internal tooth, and rack-and-pinion.



External-tooth gears 

           The most common type of spur gear, has teeth cut on the outside perimeter of mating cylindrical wheels, with the larger wheel called the gear and the smaller wheel the pinion.The simplest arrangement of spur gears is a single pair of gears called a single reduction stage, where output rotation is in a direction opposite that of the input. In other words, one is clockwise while the other is counter-clockwise.
Higher net reduction is producedwith multiple stages inwhich the driven gear is rigidly connectedto a third gear. This third gearthen drives a mating fourth gear that serves as output for the second stage.In this manner, several output speedson different shafts can be produced from a single input rotation.


Internal (ring) gears 

             Ring gears produce an output rotation that is in the same direction as the input, As the name implies, teeth are cut on the inside surface of a cylindrical ring, inside of which are mounted a single external-tooth spur gear or set of external-tooth spur gears, typically consisting of three or four larger spur gears (planets) usually surrounding a smaller central pinion (sun). Normally, the ring gear is stationary, causing the planets to orbit the sun in the same rotational direction as that of the sun. For this reason, this class of gear is often referred to as a planetary system. 
      
            The orbiting motion of the planets is transmitted to the output shaft by a planet carrier.In an alternative planetary arrangement, the planets may be restrained from orbiting the sun and the ring left free to move. This causes the ring gear to rotate in a direction opposite that of the sun. By allowing both the planet carrier and the ring gear to rotate, a differential gear drive is produced, the output speed of one shaft being dependent on the other.


Rack-and-pinion gears

                A straight bar with teeth cut straight across it is called a rack.Basically, this rack is considered to be a spur gear unrolled and laid out fiat.Thus, the rack-and pinion is a special case of spur gearing. The rack-and-pinion is useful in converting rotary motion to linear and vice versa. Rotation of the pinion produces linear travel of the rack. Conversely, movement of the rack causes the pinion to rotate.The rack-and-pinion is used extensively in machine tools, lift trucks, power shovels, and other heavy machinery where rotary motion of the pinion drives the straight-line action of a reciprocating part. Generally, the rack is operated without a sealed en-closure in these applications, but some type of cover may be provided to keep dirt and other contaminants from accumulating on the working surfaces.



What are Helical Gears & give their classification?

                 


                      Helical gearing differs from spur in that helical teeth are cut across the gear face at an angle rather than straight,Thus, the contact line of the meshing teeth progresses across the face from the tip at one end to the root of the other, reducing the noise and vibration characteristic of spur gears. Also, several teeth are in contact at any one time, producing a more gradual loading of the teeth that reduces wear substantially.
                The increased amount of sliding action between helical gear teeth, however, places greater demands on the lubricant to prevent metal-to-metal contact and resulting premature gear failure. Also, since the teeth mesh at an angle, a side thrust load is produced along each gear shaft. Thus, thrust bearings must be used to absorb this load so that the gears are held in proper alignment. The three other principle classes of helical gears are: double-helical, herringbone,and cross-helical.

Double-helical gears  

               Thrust loading is eliminated by using two pairs of gears with tooth angles opposed to each other. In this way, the side thrust from one gear cancels the thrust from the other gear. These opposed gears are usually manufactured with a space between the opposing sets of teeth.

Herringbone gears  

            


             Teeth in these gears resemble the geometry of a herring spine, with ribs extending from opposite sides in rows of parallel, slanting lines. Herringbone gears have opposed teeth to eliminate side thrust loads the same as double helicals, but the opposed teeth are joined in the middle of the gear circumference. This arrangement makes herringbone gears more compact than double-helicals. However, the gear centers must be precisely aligned to avoid interference between the mating helixes.

Cross-helical gears 

              This type of gear is recommended only for a narrow range of applications where loads are relatively light. Because contact between teeth is a point instead of a line, the resulting high sliding loads between the teeth requires extensive lubrication.Thus, very little power can be transmitted with cross helical gears.


Explain Bevel Gears & their classification?



               

               Unlike spur and helical gears with teeth cut from a cylindrical blank, bevel gears have teeth cut on an angular or conical surface. Bevel gears are used when input and output shaft center lines intersect. Teeth are usually cut at an angle so that the shaft axes intersect at 90 deg, but any other angle may be used. A special class of bevels called miter gears have gears of the same size with their shafts at right angles. Often there is no room to support bevel gears at both ends because the shafts intersect. 

                  Thus, one or both gears overhang their supporting shafts. This overhung load (OHL) may deflect the shaft, misaligning gears, which causes poor tooth contact and accelerates wear. Shaft deflection may be overcome with straddle mounting in which a bearing is placed on each side of the gear where space permits. There are two basic classes of bevels: straight-tooth and spirals.


Straight-tooth bevels 

                These gears, also known as plain bevels, have teeth cut straight across the face of the gear. They are subject to much of the same operating conditions as spur gears in that straight tooth bevels are efficient but somewhat noisy. They produce thrust loads in a direction that tends to separate the gears.

Spiral-bevels 

               Curved teeth provide an action somewhat like that of a helical gear, Figure 10. This produces smoother,quieter operation than straight-tooth bevels. Thrust loading depends on the direction of rotation and whether the spiral angle at which the teeth are cut is positive or negative.



Explain Hypoid Gears & their classification?



            Hypoid gears resemble spiral bevels, but the shaft axes of the pinion and driven gear do not intersect.This configuration allows both shafts to be supported at both ends. In hypoid gears, the meshing point of the pinion with the driven gear is about midway between the central position of a pinion in a spiral-bevel and the extreme top or bottom position of a worm. This geometry allows the driving and driven shafts to continue past each other so that end-support bearings can be mounted. These bearings provide greater rigidity than the support provided by the cantilever mounting used in some bevel gearing. 

                Also adding to the high strength and rigidity of the hypoid gear is the fact that the hypoid pinion has a larger diameter and longer base than a bevel or spiral-bevel gear pinion of equal ratio. Although hypoid gears are stronger and more rigid than most other types, they are one of the most difficult to lubricate because of high tooth-contact pressures. Moreover, the high levels of sliding between tooth surfaces reduces efficiency. Infact, the hypoid combines the sliding action of the worm gear with the rolling movement and high tooth pressure associated with the spiral bevel. In addition, both the driven and driving gears are made of steel, which further increases the demands on the lubricant. 

               As a result, special extreme pressure lubricants with both oiliness and anti-weld properties are required to withstand the high contact pressures and rubbing speeds in hypoids. Despite these demands for special lubrication, hypoid gears are used extensively in rear axles of automobiles with rear-wheel drives. Moreover, they are being used increasingly in industrial machinery.


What is a WORM & WORM WHEEL?

                                                       

                           Worm gear sets, consist of a screw-like worm (comparable to a pinion) that meshes with a larger gear, usually called a wheel. The worm acts as a screw, several revolutions of which pull the wheel through a single revolution. In this way, a wide range of speed ratios up to 60:1 and higher can be obtained from a single reduction. Most worms are cylindrical in shape with a uniform pitch diameter. However, a double enveloping worm has a variable pitch diameter that is narrowest in the middle and greatest at the re ends.

                    This configuration allows the worm to engage more teeth on the wheel, thereby increasing load capacity.In worm-gear sets, the worm is most often the driving member. However, a reversible worm-gear has the worm and wheel pitches so proportioned that movement of the wheel rotates the worm. In most worm gears, the wheel has teeth similar to those of a helical gear, but the tops of the teeth curve inward to envelop the worm. As a result, the worm slides rather than rolls as it drives the wheel. Because of this high level of rubbing between the worm and wheel teeth, the efficiency of worm gearing is lower than other major gear types. 

                  One major advantage of the worm gear is low wear, due mostly to the full-fluid lubricant film that tends to be formed between tooth surfaces by the worm sliding action. A continuous film that separates the tooth surfaces and prevents direct metal-to-metal contact is typically provided by a relatively heavy oil, which is often compounded with fatty or fixed oils such as acid less tallow oil. This adds film strength to the lubricant and further reduces friction by increasing the oiliness of the fluid.


Explain RACK & PINION MECHANISM?







                   A rack is a toothed bar or rod that can be thought of as a sector gear with an infinitely large radius of curvature. Torque can be converted to linear force by meshing a rack with a pinion: the pinion turns; the rack moves in a straight line. Such a mechanism is used in automobiles to convert the rotation of the steering wheel into the left-to-right motion of the tie rod(s). Racks also feature in the theory of gear geometry, where, for instance, the tooth shape of an interchangeable set of gears may be specified for the rack (infinite radius), and the tooth shapes for gears of particular actual radii then derived from that. The rack and pinion gear type is employed in a rack railway














                 

Cadillac World Thorium Fuel Concept Car

                

Thorium Fuel Concept Car

            The future hasn't quite turned out like we expected. While Saturday-morning cartoons promised us a world in which our fantasy-powered flying bubble cars would conveniently origami themselves into easily-transportable briefcases, reality has been a bit slower to abandon the traditional internal-combustion model. But that may eventually change. Scientists at research-and-development firm Laser Power Systems are working on a new turbine electric generator system powered by a thorium-based laser. If, like us, you spent the majority of chemistry class studiously analyzing the insides of your eyelids, you may not recall that thorium is a mildly radioactive metal with an atomic weight of 90.

WTF
      
Working Principle:

          The principle is fairly simple. The thorium would be lased to generate heat, which would then produce steam in a closed-loop system. That steam would then power a generator to produce electricity. Since it only takes a thin sheet of aluminum foil to shield the world from the weak thorium radiation and the element can't be weaponized, it's thought to be perfect for mobile power generation.










             Scientists say that just eight grams of thorium could be enough to power a vehicle for somewhere around 300,000 miles of driving. If this all sounds a little far-fetched, it may pay to remember that thorium is already on automakers' radar. Cadillac introduced the thorium-powered World Thorium Fuel Concept at the 2009 Chicago Auto Show.

World's first wooden supercar


                 
  •                  The world's first wooden super car has been unveiled - and it's faster than a Porsche or a Lamborghini.The 'Splinter' car can turn out a whopping 700bhp from its twin supercharged, 4.6litre V8 engine - almost 300bhp more than a Porsche 911.And with a top speed of a staggering 240mph, it will leave the Porsche or even the brand new Lamborghini Revanton trailing in its wake.


  1. The entire car, which is made from a combination of maple, plywood and MDF, weighs just 1,134kg - some 240kg less than the super lightweight Porsche.
  2. The eco-friendly two seater, which is fitted with a six-speed, manual gearbox, can sprint from 0 to 60mph in just over three seconds.
  3. But despite its awesome power, designers say the stylish petrol driven car will still be able to do up to 20mpg.
  4. Designer Joe Harmon, who is head of the project, said: "Wood is a truly amazing material to work with.
  5. "It has a higher strength-to-weight ratio than aluminium or steel, and it possesses a versatility that makes many different types of construction techniques possible.
  6. "The look, feel, and smell of a natural material like wood is not seen elsewhere and cannot be faked, and the satisfaction involved in making something from a piece of wood is awesome.
  7. "This is a supercar designed to push boundaries and prove the potential of wood as a material."







Carefully carved: 
  • The car is made completely out of wood
  • The 15ft-long car has a laminated wood veneer chassis and wooden wheel rims inside giant 20 inch diameter tyres.
  • Suspension is provided through laminated wooden arms and springs made from orange wood.
  • Joe, from North Carolina, US, added: "The light weight is achieved through careful design and composite construction.
  • "The Splinter is not made from any carved-out, solid chunks of wood, but rather moulded laminates."


                           

Under the bonnet: 

  • The wooden car can reach a top speed of 240mph
  • The car is due to hit the road later this year. The design company, Joe Harmon Design, has not yet decided on a price for the supercar.
  • And according to 27-year-old Joe, it might not be long before Formula One star Lewis Hamilton is behind the wheel of a wooden car.
  • He said: "An F1 car could definitely be made from wood.
  • "Some extremely creative engineering would have to go into it to overcome the strength-to-weight and mouldability benefits of carbon fibre, but it's definitely possible.
  • "Getting permission to race it would probably be a bigger challenge than engineering it. But it would be fun to try."
  • Drivers are kept safe by a roll cage which also stiffens the chassis and defines the rear profile of the car.

Components of Hydraulic System and their functions


RESERVOIR: 

The tank which stores the working medium (oil) and supplies to pump and also takes back the return and drain oil in a hydraulic system and protects the medium from external contamination is called Reservoir. It also allows the oil to cool through its walls and allows contaminants to settle and air to separate. Generally in many cases it houses cooler, return filters, air breather( a device which allows air to move in and out of a
container to maintain atmospheric pressure), level indicator, level switches (float switches).

SUCTION LINE:

The pipe line connecting tank to pump generally with a shut off valve in between is called suction line. Without opening this valve, pump should not be started. Generally a hose or rubber bellows is provided in this line to isolate the vibrations of the pump.

PUMP: 

The element which transfers oil/fluid from one point to another point or which gives flow is called pump. Pump only gives flow, but the resistance to flow develops pressure. In hydraulics only positive displacement pumps are used. In these pumps there is positive sealing between suction and delivery. For every revolution of pump, a fixed amount of oil is transferred from suction to delivery irrespective of load conditions.
Practically there will be minor internal leakages which are negligible. This fixed amount of oil transferred is called Displacement of pump. The displacement when multiplied by speed of the electric motor driving the pump, gives Discharge of the pump (flow of the pump) Centrifugal pumps (non positive displacement type) are not used in hydraulic systems. In this if delivery is closed, pressure will not build up beyond a particular limit. Safety valve is not required. Most commonly used positive displacement pumps used in hydraulics are
Gear, piston and vane types are popular. A positive displacement pump should never be started without opening the suction valve. There should be sufficient oil level in tank so that air does not enter the pump. If air enters the pump, it will run with high noise and it will be damaged very soon. This is called aeration. Even though sufficient oil is there,aeration can occur due to any loose pipe joints in suction line. Pump is always followed by a relief valve (safety valve), pressure gauge, check valve and shut off valve.

CHECK VALVE/NON-RETURN VALVE:

 It is a valve which allows flow in one direction only. Generally provided after the pump in most of the cases to take care of reverse rotation of pump. It is also used in many places of the circuit as a bypass etc. Check
valve and non-return valve are same.

PRESSURE GAUGE:

It is provided to know the pressure and for setting of various
valves, pressure switches.


SAFETY VALVE/ RELIEF VALVE: 

Both are same and it is the most important component of Hydraulic system. It limits the maximum pressure in the system so that elements, hoses, cylinders, pipes etc does not burst due to high pressure. I t also protects
the equipment and system from over loading. When the system pressure increases beyond the set point, the safety valve opens and relieves the excess oil to tank.

ACCUMULATOR:

 It is a reservoir of pressurized hydraulic fluid i.e. storage of energy by means of spring or compressed nitrogen, dead weight. It is basically a pressure vessel. No welding is allowed on this. 
1. Bladder type
2.Piston type 
3.Dead
weight type
4. Direct gas loaded type.
Nitrogen is generally used in accumulators but never use oxygen as it may result in explosion. You should never open a pressure line with accumulator in line. Always isolate/preferably drain the accumulator before starting the job.Accumulator is used 
(a) for smooth functioning of HS without pressure and flow fluctuations 
(b) as an emergency power source for essential operations in case of power failure. 
(c) for holding pressure for long times in a circuit (d) a big pump can be replaced by a small pump ( cost & energy saving) and many other purposes.

DIRECTION CONRTOL VALVES:

 Distributor/Master valve / DC valve are all same. If a pump supplies oil directly to a cylinder, it is not possible or convenient to control the load or to change the direction of motion. Hence a dc valve is provided in between pump and the load cylinder to stop/start /reverse the motion of the load. DC valve can be activated by a lever, cam, solenoid, pedal, pneumatic/hydraulic pressure depending on the design and requirement. Most commonly used are solenoid operated and they are having two/ three positions. If you are using a two position valve you cannot stop the cylinder in between.

There are many varieties of dc valves.

FLOW CONTROL VALVES:

 To control the speed of the actuator /load, the amount of oil flowing into the cylinder is controlled by means of these valves. Generally these are provided before the cylinder or in branch circuits where flow is to be controlled. Simple needle/globe valve can also be used as flow control valve in some cases.

SEQUENCE VALVE: 

In a simple punching machine, the job is held in position by a clamping cylinder at low pressure and then a hole is punched by another cylinder at a high pressure. Now these two cylinders are always to be operated in definite sequence only. This sequence can be achieved by electrical/mechanical or by hydraulic means through a valve called sequence valve. Hydraulic sequencing is most common and versatile. A dc valve supplies oil to cylinder-1 and through a sequence valve to cylinder -2. It is almost similar to a safety valve but not same.

PRESSURE REDUCING VALVE:

 In some HS many cylinders are working at different pressures ,but a few cylinders does not require full pressure and can work at a low pressure .Then all these selected cylinders are supplied oil through a valve known as pressure reducing valve. In pressure reducing valve, the output pressure cannot go beyond a particular limit. This setting will be lower than the safety valve setting. 


FILTERS:

All hydraulic elements work under close tolerances and they are precision items with mirror surface finish.Contaminants and dust are the single largest enemy of the HS as they cause malfunctioning and jamming of valves and fast wear out of elements. The contaminants are internally generated in the system and some are external to the system. Working medium is to be regularly cleaned from these contaminants. Hence oil filters are used in suction line, pressure line and return line and before an important precision valve/pump as per the need. This will improve the performance of the system.The coarse filter used in suction line of pump sometimes is called STRAINER .Hydraulic systems are most reliable, if the contamination is kept under control, and breakdowns can be minimized. In a filter the hydraulic oil is allowed to pass through a porous medium (like clay, paper, wire mesh, synthetic fiber etc) so that the dust particles and other contaminants are retained and only clean oil goes ahead into the system.Offline filtration (mostly portable) systems are also used for up keeping the system depending on the criticality. Electrostatic Liquid cleaners are also used nowadays. These are very simple to operate and cheap.

PRESSURE SWITCH: 


The hydraulic oil under pressure pushes a small plunger which in turn makes/breaks an electrical contact. These are provided in the system for safety and efficient operation or for achieving a particular logic sequence. Contact Manometer is a pressure gauge with electrical contacts, which does almost the same job, but they are less reliable and less robust.

LEVEL SWITCHES: 

Generally the reservoir is provided with low level and high level float switches, so that they give alarm of low oil level/ high level and can be used for interlocking purpose. Float switch operates due to buoyancy in oil. Generally the low level switch is interlocked with the drive of pump, so that when there is no oil due to any reason, the pump will trip or will not allow the pump to start.

ACTUATORS:

Generally the hydraulic cylinders and hydraulic motors are called actuators. These actuators do the actual job of lifting/lowering/pushing/rotating /holdingetc . Hydraulic motor replaces many applications of electric motors due to many advantages like speed control, over load protection etc. Hydraulic motors are almost similar to pumps. When these are supplied oil at pressure, they will give rotary output. Generally gear/vane
/piston motors are in use.Generally two types of Hydraulic cylinders are commonly used viz,
 a) Double acting cylinders, which can be used for pulling and pushing ,consists of piston , piston rod, body covers, seals and fasteners, eye . Basically a sealed piston with rod reciprocates inside a cylindrical body under the pressure of oil..


B) Single acting cylinder.
 These types can only push/lift a load. The single acting cylinder cannot retract due to hydraulic force. It retracts due to weight/spring/ load. Hydraulic jacks are generally single acting type. 


SEALS: 

The component which prevents the motion of the fluid in the undesired direction is called seal/packing. Can also be defined as that component that separates two fluids. The functions of the seal are 
a) to seal the hydraulic fluid in a closed chamber
 b) Maintains pressure 
c)stops dirt/water/contamination from entering the system 
d) separates two
fluids
e) performs any combination of the above functions.
In simple terms a seal stops internal or external leakages. Cost of the seal is a small fraction, but determines the efficiency of the system. Problems associated with seals: Wastage of fluid leaked, fire hazards, slippery floor,makes equipment and products dirty, environment pollution, depleting natural resources.Leather, cork, ropes are the oldest seals, which are widely used in the earlier days. Then natural rubbers, synthetic rubber , PTFE, Polyurethane, POM etc are used nowadays. Seals should be handled delicately, and sharp tools should not be used.

PIPES, FITTINGS, CLAMPS: 

Generally pickled, flushed seamless pipes are used in hydraulic systems. For maintenance convenience and ease of laying, pipe joints are provided at suitable places. For small pipes union joints are used and in bigger pipes flange joints are used. There is large variety of pipe joints of different standards and designs are
available. Care should be taken that different fittings do not get mixed up. Also while doing maintenance on fittings thread type/seat design/size etc should be matched. Otherwise lot of problems will result. Pipes should be properly clamped and supported; otherwise the joints get loosened during working due to vibrations. Pipe clamps are made of wood/ Aluminium/ synthetic materials. Wooden clamps are to be avoided due to environment protection. Aluminium clamps are used where high temperatures are there. Synthetic clamps are commonly used nowadays. While laying hose pipes, the layout should be
smooth, and they should not crisscross/twist/entangle and rub each other.