COMPARISON OF GRP/FRP CABLE TRAYS V/S METAL CABLE TRAYS

1.Corrosion Resistance
GRP/FRP - Excellent corrosion resistance against sea water and most chemical fumes

METAL - Poor corrosion resistance, pitting takes place even in SS or aluminum in sea water. Galvanic Corrosion takes place between Stainless Steel trays and MS supports

2.Hot Working
GRP/FRP -No Hot working, all assembly by Nut & Bolts

METAL -Hot working , welding cutting and joining requires special permission in hazardous areas

3.Light weight
GRP/FRP -Sp.gr. 1.9, 1/4th that of steel, even lighter than Aluminum(sp.gr.2.8), just one person required to lift a big size cable ladder, so very easy and fast Installation, saving time and money

METAL -Very heavy, 4 times to GRP/FRP, hence crane or 3 people required to lift a cable ladder

4.Fire Retardant
GRP/FRP -Meets most stringent offshore fire resistance norms as per British, ASTM and UL specifications

METAL -In heavy fire even steel de-shapes and needs replacement

5.Installation Cost
GRP/FRP -Very low, as lighter in wt hence only one man can lift, and very easy to cut and fabricate at site, thus faster installation and easy site adjustment and modifications

METAL -HIGH, needs 2-3 persons or special equipment to lift, also difficult to cut and refabricate as per site requirement as cutting takes time.

6.Risk of cable damage
GRP/FRP -Very low, as being plastics have much less hardness and even its sharp edges cannot damage a cable

METAL -When any site modification is done, sharp edges are created in metal which can cause damage to cables and pose risk of current.

7.High insulation ands Safe
GRP/FRP -No earthing of cable tray is required as it has high Insulation value. In case of any cable stripping, the tray being Insulated is safe for the Humans.

METAL -Earthing is must, hence cost of earthing increases overall cost, which is not generally considered when evaluating.

8.Part consolidation
GRP/FRP -As GRP/FRP is extruded section, inbuilt ribs for reinforcement, collars for fixing covers are possible in single section

METAL -This is not possible in metal, and if welding is done it looks very bad.

9.U.V. resistance
GRP/FRP -All GRP/FRP cable Trays are made from very high U.V. additives, in addition to special surfacing Veils for glass blooming prevention, and carbon black for additional U.V protection

METAL -N/A

10.Antistatic
GRP/FRP - Cable trays are available in antistatic option as well for oil hazardous areas on demand, thus safe even in hydrocarbon atmosphere.

METAL -N/A

11.First Time COST
GRP/FRP - FRP/GRP cable trays are competitive to SS trays with all above advantages

METAL -SS trays are very costly compared to GRP/FRP Trays

FRP or GRP Cable Ladder/Tray

General
Known as glass-reinforced plastic (GRP) in Britain, fibre-reinforced plastic (FRP) in the USA, or by the trade name fibreglass (after the manufacturing company Fibreglass Ltd.), GRP has been used for a wide range of applications from car body panels and boat hulls to furniture and tennis rackets. It has the virtue of a good weight to strength ratio, rust resistance, and ability to be moulded in a wide variety of ways. It became increasingly widely used in the post-Second World War period, a pioneering design being the celebrated DAR Armchair by Charles and Ray Eames for the 1948 Low-Cost Furniture Design Competition at the Museum of Modern Art in New York. Very much paralleled by the organic forms found in much contemporary product, train, and automobile design in Italy, the flowing, sculptural form of the seat (supported on a metal frame) expressed the creative possibilities of the new medium. These were realized in subsequent designs such as Eero Saarinen's elegant Tulip armchair of 1956. Verner Panton was another designer to explore the expressive qualities of the medium in his moulded, cantilevered chair of 1960 first manufactured in West Germany. Many furniture designs first manufactured in GRP have subsequently been manufactured in ABS plastic. Early use of GRP in automobile manufacture included the roof of the Citroen DS (1955) and the body panels of the Chevrolet Corvette (1953). From the 1970s improved production processes engendered more widespread uses in architecture and interior design, whether in terms of weather resistant details and services or bathrooms.





Definition of FRP Composites


Not all plastics are composites. In fact, the majority of plastics today are pure plastic, like toys and soda bottles. When additional strength is needed, many types of plastics can be reinforced (usually with reinforcing fibers). This combination of plastic and reinforcement can produce some of the strongest materials for their weight that technology has ever developed...and the most versatile.

Therefore, the definition of a fiber-reinforced polymer (FRP) composite is:
A combination of

- a polymer (plastic) matrix (either a thermoplastic or thermoset resin, such as polyester, isopolyester, vinyl ester, epoxy, phenolic)

- a reinforcing agent such as glass, carbon, aramid or other reinforcing material


such that there is a sufficient aspect ratio (length to thickness) to provide a discernable reinforcing function in one or more directions. FRP composite may also contain:

- fillers

- additives

- core materials


that modify and enhance the final product. The constituent elements in a composite retain their identities (they do not dissolve or merge completely into each other) while acting in concert to provide a host of benefits ideal for structural applications including:

High Strength and Stiffness Retention - composites can be designed to provide a wide range of mechanical properties including tensile, flexural, impact and compressive strengths. And, unlike traditional materials, composites can have their strengths oriented to meet specific design requirements of an application.

-Light Weight/Parts Consolidation - FRP composites deliver more strength per unit of weight than most metals. In fact, FRP composites are generally 1/5th the weight of steel. The composite can also be shaped into one complex part, often times replacing assemblies of several parts and fasteners. The combination of these two benefits makes FRP composites a powerful material system- structures can be partially or completely pre-fabricated at the manufacturer's facility, delivered on-site and installed in hours.

-Creep (Permanent Deflection Under Long Term Loading) - The addition of the reinforcement to the polymer matrix increases the creep resistance of the properly designed FRP part. Creep will not be a significant issue if the loads on the structure are kept below appropriate working stress levels.

-Resistance to Environmental Factors - Composites display excellent resistance to the corrosive effects of:
-Freeze-thaw: because composites are not attacked by galvanic corrosion and have low water absorption, they resist the destructive expansion of freezing water.

-Weathering and Ultra-Violet Light: FRP composite structures designed for weather exposure are normally fabricated with a surface layer containing a pigmented gel coat or have an ultraviolet (UV) inhibitor included as an additive to the composite matrix. Both methods provide protection to the underlying material by screening out UV rays and minimizing water absorption along the fiber/resin interface.

-Chemicals and Temperature: Composites do not rust or corrode and can be formulated to provide long-term resistance to nearly every chemical and temperature environment. Of particular benefit, is composites ability to successfully withstand the normally destructive effects of de-icing salts and/or saltwater spray of the ocean.



-Fire Performance of Composites - FRP composites can burn under certain conditions. Composites can be designed to meet the most stringent fire regulations by the use of special resins and additives. Properly designed and formulated composites can offer fire performance approaching that of most metals.

THE 4-20mA CURRENT LOOP

THE 4-20mA CURRENT LOOP
The 4-2OmA current loop has been with us for so longthat it's become rather taken for granted in the industrialand process sectors alike. Its popularity comes from itsease of use and its performance. However, just becausesomething is that ubiquitous doesn't mean we're allnecessarily getting the best out of our current loops.
A big benefit of the current loop is its simple wiring justthe two wires. The supply voltage and measuring currentare supplied over the same two wires. Zero offset of thebase current (ie. 4mA) makes cable break detection simple:if the current suddenly drops to zero, you have a cable break.In addition, the current signal is immune to any stray electricalinterference, and a current signal can be transmitted overlong distances.

Typical wiring for current output transducer.
You can think of the current loop itself as being analogousto a water system. You have a hose pipe (the wires) anda source tap (the power supply). You have a spray gunthat regulates the flow (the transducer). You can haveother equipment on the line, but it all has to be connectedtogether in a ring Ioop. The more holes (devices) you haveon the hose pipe, the higher the pressure will be requiredfrom the tap. Relating all that back to the current loop,you see a power supply, a transducer and one or morepieces of instrumentation all connected together in a ring.
You'll often hear things referred to as being either activeor passive. Some instruments have an active output whichincludes both the control of the current in the loop as wellas provide the supply voltage. This is typically specifiedas being a 4-20mA output into 10-750 Ohms, or somethingsimilar. A passive input would be a simple resistor input thathas a voltage drop to be factored into the equation oncethe supply voltage is chosen. This is typically specified asa 4-20mA input into 10 Ohm.
Working out the power supply requirement is a simple matterof adding up all the units in the loop at maximum currentof 20mA. As an example, suppose you have a sensor'regulator' which requires minimum 12V DC and instrumentationof 10 Ohm input:
10 Ohm x 20mA = 0.2V
So, for this circuit, a 12.2V minimum supply is required, thesensor's maximum voltage might be specified at 30V, so a24V supply would be all the circuit requirements with sparecapacity to boot.
In order to measure the current loop it is necessary to breakthe loop and insert a current meter into it. You can alsomeasure the voltage across the various components by inthe loop, such as the voltage out of the power supply, thevoltage over a sensor, and the voltages over the variouspieces of instrumentation. This information will give you agood picture of what is happening within the loop.

Multi-instrument 4-20mA current loop with panel meter,chart recorder, computers, etc.
A question which is sometimes asked is whether it is possibleto use single power supply over several loops. This is possible,but you have to ensure that the power supply can give enoughcurrent to meet the needs of multiple loops. It is also thecase that the current loops will have the same zero negativereference, which can cause a ground loop. In addition,interference from one loop can affect all the other loopsdriven from the one supply.
This article is printed with the kind permission ofMorten Moller, who runs an internet support andconsultancy business and can be contacted atmorten@askmorten.co.ukHis website is at http://www.askmorten.co.uk/

NEMA Enclosure Types

NEMA PC Enclosure Types

http://www.industrial-computer-enclosure.co.uk/NEMA4.htm

This document provides general information on the definitions of NEMA Enclosure Types
Definitions[From NEMA 250-1997]

In Non-Hazardous Locations, the specific enclosure Types, their applications, and the environmental conditions they are designed to protect against, when completely and properly installed, are as follows:

Type 1 - The unit is constructed for indoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment and to provide a degree of protection against falling dirt.

Type 2 - Enclosure constructed for indoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment, to provide a degree of protection against falling dirt, and to provide a degree of protection against dripping and light splashing of liquids.

Type 3 - Pc cabinet constructed for either indoor or outdoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt, rain, sleet, snow, and windblown dust; and that will be undamaged by the external formation of ice on the enclosure.

Type 3R - Cabinet constructed for either indoor or outdoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt, rain, sleet, and snow; and that will be undamaged by the external formation of ice on the enclosure.

Type 3S - Computer cabinet constructed for either indoor or outdoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt, rain, sleet, snow, and windblown dust; and in which the external mechanism(s) remain operable when ice laden.

Type 4 - Computer enclosures constructed for either indoor or outdoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt, rain, sleet, snow, windblown dust, splashing water, and hose-directed water; and that will be undamaged by the external formation of ice on the enclosure.

Type 4X - protection unit constructed for either indoor or outdoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt, rain, sleet, snow, windblown dust, splashing water, hose-directed water, and corrosion; and that will be undamaged by the external formation of ice on the enclosure.

Type 5 - computer enclosure constructed for indoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt; against settling airborne dust, lint, fibres, and flyings; and to provide a degree of protection against dripping and light splashing of liquids.

Type 6 - PC Enclosures constructed for either indoor or outdoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt; against hose-directed water and the entry of water during occasional temporary submersion at a limited depth; and that will be undamaged by the external formation of ice on the enclosure.

Type 6P - cabinet constructed for either indoor or outdoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt; against hose-directed water and the entry of water during prolonged submersion at a limited depth; and that will be undamaged by the external formation of ice on the enclosure.

Type 12 - computer cabinet constructed (without knockouts) for indoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt; against circulating dust, lint, fibres, and flyings; and against dripping and light splashing of liquids.

Type 12K - Enclosures constructed (with knockouts) for indoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt; against circulating dust, lint, fibres, and flyings; and against dripping and light splashing of liquids.

Type 13 - Enclosures constructed for indoor use to provide a degree of protection to personnel against incidental contact with the enclosed equipment; to provide a degree of protection against falling dirt; against circulating dust, lint, fibres, and flyings; and against the spraying, splashing, and seepage of water, oil, and non-corrosive coolants.

PC Enclosure Classification Designations

IEC Publication 60529 Classification of Degrees of Protection Provided by Enclosures provides a system for specifying the enclosures of electrical equipment on the basis of the degree of protection provided by the enclosure. IEC 60529 does not specify degrees of protection against mechanical damage of equipment, risk of explosions, or conditions such as moisture (produced for example by condensation), corrosive vapours, fungus, or vermin. The NEMA Standard for Enclosures for Electrical Equipment does test for environmental conditions such as corrosion, rust, icing, oil, and coolants. For this reason, and because the test and evaluations for other characteristics are not identical, the IEC Enclosure Classification Designations cannot be exactly equated with the enclosure Type numbers in this Standard.

The IEC designation consists of the letters IP followed by two numerals. The first characteristic numeral indicates the degree of protection provided by the enclosure with respect to persons and solid foreign objects entering the enclosure. The second characteristic numeral indicates the degree of protection provided by the enclosure with respect to the harmful ingress of water.
Table A-1 provides an equivalent conversion from the enclosure Type numbers in this Standard to the IEC Enclosure Classification Designations. The enclosure type numbers meet or exceed the test requirements for the associated IEC Classification; for this reason Table A-1 cannot be used to convert from IEC Classifications to enclosure Type numbers.
Table A-1 [From NEMA 250-1997]
Conversion of Enclosure Type numbers to IEC Classification Designations
Cannot be used to convert IEC Classification Designations to NEMA Type numbers

Enclosure

NEMA -IEC IP


1 -IP10

2 -IP11

3 -IP54

3R- IP14

3S -IP54

4 and 4X- IP56

5 -IP52

6 AND 6P- IP67

12 AND 12K -IP52

13- IP54