Sunday, July 4, 2010

Our PRODUCTS for COAL MINES

ELECTRICALS

FLP/WP  well Glass
FLP/WP Tube Light Fittings
FLP/WP  Lighting (CFL)
FLP/WP Head and Tail Lamp
FLP/WP Miners Cap Lamp

FLP/WP Audio Visual system for mobile equipment





INSTRUMENTATION and ELECTRONICS

FLP/WP Limit Switch
FLP/WP Float Switch
FLP/WP Level Switch
FLP/WP Gas detection Kit
FLP/WP Temperature Switch


FLP/WP Push Button Station
FLP/WP R/S

Float Switch

The Series 100 is equipped with flanged hambers to simplify system checks or scheduled maintenance. It is available with a variety of mounting configurations such as side/side, side/bottom, side/side/bottom drain.

APPLICATION

For Liquid Level Alarm or Liquid Level Control

SPECIFICATION

Mounting External Chamber on Side
of Tank (vertical)

Sp. Gravity 0.7 and above

Pressure/Temp. Rating 40 Bar at 40 Deg. C or 18
Bar at 400 Deg. C, others
on request

Process Connection Flanged, Socket Weld or
Screwed

Connection Typel Side/Side or Side/Bottom

Chamber Material CS, SS 304/316, other
materials on request

Float Material SS 316, other materials
on request

Switch Housing Die Cast Aluminum (LM6)

Type of Micro Switch

1SPDT, 2SPDT(Equal to 1DPDT) with Silver or Gold
Plated Contact
Hermetically Sealed Switches for Highly Corrosive or Highly Explosive Area

Enclosure Protection

Ex id Telephone




















ADVANCED EEC Telephone


Salient Features I
~ SS304 Key pad, magnetic receiver lock
~ Loud Ringer sound

~ Used in wide Hazardous Locations in Chemical, Petrochemical industries, Refineries, COAL and OIL mines, etc.

Saturday, July 3, 2010

SAFETY Alert

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Call back

Electric shock from a light fitting

Click here to view resource.

    Click a tab to view specific information about this listing...
  • MIRMgate

What

A mineworker received an electric shock when his forearm made contact with a flameproof Burn Brite fluorescent light fitting (Certificate No AUS EX 424X) on a continuous miner in the hazardous zone of a coal mine. The victim was transported to hospital in accordance with the mines electric shock protocol and was allowed to leave after medical tests and examination determined that no permanent injury had occurred...

Why

The three factors of: 1. A failure of the ingress protection ; 2. Unearthed external metal on the Burn Brite light fitting, and ; 3. The 500 mA/250 ms setting of the earth leakage protection, combined to present two separate hazards in the hazardous zone of the coal mine. These hazards were; 1. A touch voltage was able to deliver an electric shock to a mineworker,; AND 2. The explosion-protected equipment failed to contain the electrical energy within the enclosure under fault conditions creating a potential source of ignition of methane

Recommendations

The issues raised herein may also apply to other light fittings and on other machinery at NSW mines. ; Manufacturers of light fittings and continuous miners, should review the risks to safety from their products and to promptly stipulate earthing, protection, maintenance and inspection requirements to their customers as required by the NSW OHS Act...





Source

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Indian Oil GM, 8 others held for Jaipur depot fire that killed 11

Indian Oil Corporation’s (IOC’s) general manager for Rajasthan Gautam Ghosh and eight of his senior colleagues were arrested on Friday for negligence that led to the death of 11 people in the 12-day fire in the oil major’s Jaipur depot in October-November 2009.

All nine officials have been charged under Section 304A IPC (causing death due to negligence) along with sections of the Petroleum Act, police said.

“We began an investigation soon after the fire, which concluded with the arrest of nine IOC officials. The investigation team, working with petroleum experts, recreated the scene before the fire broke out,” B L Soni, I-G, Jaipur range, said.

The arrested officials were responsible for gross violations of procedures laid down by the Oil Industry Safety Directorate (OISD) and IOC’s safety manual, Soni added.

The arrested officials, besides Gautam Ghosh, are, operations manager Rajesh Syal, senior manager (operations) Shashank Shekhar, senior terminal manager K S Kanodia, terminal manager Arun Pottdar, deputy manager Kapil Goyal, operating officer A K Gupta, deputy general manager in the pipelines division S S Gupta, and charge man K N Agarwal.



Source

Hazloc Guide

Hazardous Area Guide
A guide to the use of electrical equipment in potentially explosive atmospheres
To view this document in PDF format click here

Introduction

Potentially Explosive Atmospheres exist where there is a risk of explosion due to mixtures of gas/air, vapour/air, dust/air or other flammable combinations.

In such areas there is a necessity to eliminate sources of ignition such as sparks, hot surfaces or static electricity which may ignite these mixtures.

Where electrical equipment has to be used in these areas it must be so designed and constructed as to not create sources of ignition capable of igniting these mixtures.

Before electrical equipment can be used in a potentially explosive atmosphere a representative sample has to be fully tested and certified by an independent authority such as BASEEFA in the U.K. or UL in the U.S.A.

This information is intended as a guide only and further expert guidance should be sought before placing into service, maintaining or repairing any item of equipment in a Potentially Explosive Atmosphere.

Where comparisons are shown between, for example, European and North American practice this may be an approximation and individual standards/codes of practice should be consulted for precise details.

MEDC have spent 25 years designing and manufacturing electrical equipment suitable for use in potentially explosive atmospheres. We deal with all the major testing and certification authorities throughout the world and have a diverse range of internationally approved products.


Area Classification

Process plants are divided into Zones (European and IEC method) or Divisions (North American method) according to the likelihood of a potentially explosive atmosphere being present.

European & IEC ClassificationDefinition of zone or divisionNorth American Classification
Zone 0 (gases)An area in which an explosive mixture is continuously present or present for long periodsClass I Division 1 (gases)
Zone 20 (dusts)Class II Division 1 (dusts)
Zone 1 (gases)An area in which an explosive mixture is likely to occur in normal operationClass I Division 1 (gases)
Zone 21 (dusts)Class II Division 1 (dusts)
Zone 2 (gases)An area in which an explosive mixture is not likely to occur in normal operation and if it occurs it will exist only for a short timeClass I Division 2 (gases)
Zone 22 (dusts)Class II Division 2 (dusts)
Class III Division 1 (fibres)
Class III Division 2 (fibres)


Gas Groups (plus dusts and fibres)

There are two main gas groups, Group I – Mining only and Group II – Surface Industries
These categories are used in European and I.E.C. groupings.
Group I is concerned only with underground mining where methane and coal dust are present.
Group II
gases occurring in surface industries, are sub-grouped according to their volatility. This enables electrical equipment to be designed to less onerous tolerances if it is to be used with the least volatile gases.

Typical gas/materialEuropean/I.E.C. Gas GroupNorth American Gas Group
MethaneI-
AcetyleneIICA
HydrogenIICB
EthyleneIIBC
PropaneIIAD
Metal dust-E
Coal dust-F
Grain dust-G

Note : North American legislation now allows Zones to be used to classify areas, where this practice is used it follows the IEC Zone method.


Temperature

Hot surfaces can ignite explosive atmospheres. To guard against this all Electrical Equipment intended for use in a potentially explosive atmosphere is classified according to the maximum surface temperature it will reach in service. This temperature is normally based on a surrounding ambient temperature of 40 degrees Centigrade (102 degrees Fahrenheit). This temperature can then be compared to the ignition temperature of the gas(es) which may come into contact with the equipment and a judgement reached as to the suitability of the equipment to be used in that area.

Many MEDC products are certified for use in ambient temperatures up to 55 degrees Centigrade, see individual data sheets for details.

Temperature ClassificationMaximum Surface Temperature
European/I.E.C.North American
T1T1450° C
T2T2300° C
T2A280° C
.T2B260° C
T2C230° C
.T2D215° C
T3T3200° C
.T3A180° C
T3B165° C
.T3C160° C
T4T4135° C
.T4A120° C
T5T5100° C
T6T685° C

e.g. Butane has an ignition temperature of 365 degrees Centigrade, equipment used in the vicinity of this gas would need a T rating of T2 or higher.


Types of Electrical Equipment Suitable for
use in Potentially Explosive Atmospheres

Different techniques are used to prevent electrical equipment from igniting explosive atmospheres. There are restrictions on where these different types of equipment can be used as follows :

.European - Area of use Designation StandardIEC - Area of use Designation StandardUSA - Area of use Designation Standard
Flameproof Enclosure – An enclosure used to house electrical equipment, which when subjected to an internal explosion will not ignite a surrounding explosive atmosphere.Zones 1 & 2
EExd
EN50018
Zones 1 & 2
Exd
IEC60079-1
Class 1 Divisions 1 & 2
UL1203
Intrinsic Safety – A technique whereby electrical energy is limited such that any sparks or heat generated by electrical equipment is sufficiently low as to not ignite an explosive atmosphere.Zones 0, 1 & 2
EExi
EN50020
Zones 1 & 2
Exi
IEC60079-11
Class 1
Divisions 1 & 2
UL913
Increased Safety – This equipment is so designed as to eliminate sparks and hot surfaces capable of igniting an explosive atmosphere.Zones 1 & 2
EExe
EN50019
Zones 1 & 2
Exe
IEC60079-7
Purged and Pressurised – Electrical equipment is housed in an enclosure which is initially purged to remove any explosive mixture, then pressurised to prevent ingress of the surrounding atmosphere prior to energisation.Zones 1 & 2
EExp
EN50016
Zones 1 & 2
Exp
IEC60079-2
Class 1
Divisions 1 & 2
NFPA496
Encapsulation – A method of exclusion of the explosive atmosphere by fully encapsulating the electrical components in an approved material.Zones 1 & 2
EExm
EN50028
Zones 1 & 2
Exm
IEC60079-18
Oil Immersion – The electrical components are immersed in oil, thus excluding the explosive atmosphere from any sparks or hot surfaces.Zones 1 & 2
EExo
EN50015
Zones 1 & 2
Exo
IEC60079-6
Class 1
Division 2
UL698
Powder Filling – Equipment is surrounded with a fine powder, such as quartz, which does not allow the surrounding atmosphere to come into contact with any sparks or hot surfaces.Zones 1 & 2
EExq
EN50017
Zones 1 & 2
Exq
IEC60079-5
Non-sparking – Sparking contacts are sealed against ingress of the surrounding atmosphere, hot surfaces are eliminated.Zone 2
EExn
EN50021
Zone 2
Exn
IEC60079-15
.
Special Protection – Equipment is certified for use in a Potentially Explosive Atmosphere but does not conform to a type of protection listed above.Zones 0, 1 & 2
*Exs
Zones 0, 1 & 2
Exs

* This type of protection is only recognised by National Authorities, not as a
European-wide type of protection.


Selection, Installation and Maintenance of Electrical Equipment Intended for use in
Potentially Explosive Atmospheres

International and national standards are published giving details of requirements for the safe use of Electrical Equipment in Potentially Explosive Atmospheres as follows :

.
International
U.K.
U.S.A.
General Recommendations

EC60079-14
BS5345:Part 1
N.E.C. Chapter 5
Classification of Hazardous Areas

IEC60079-10.N.E.C. Chapter 5
Inspection and Maintenance of Electrical EquipmentIEC60079-1
Requirements for Flameproof EnclosuresIEC60079-14BS5345:Part 3N.E.C. Chapter 5
Requirements for Intrinsically Safe EquipmentIEC60079-14BS5345:Part 4N.E.C. Chapter 5
Requirements for Increased Safety EquipmentIEC60079-14BS5345:Part 6N.E.C. Chapter 5
Requirements for Purged and Pressurised EquipmentIEC60079-14BS5345:Part 5N.E.C. Chapter 5
Requirements for Non-Sparking EquipmentIEC60079-14BS5345:Part 7.
Requirements for Equipment with Special ProtectionIEC60079-14BS5345:Part 8

MEDC advise that all Explosion-proof electrical equipment is maintained, by suitably trained personnel, in accordance with the Manufacturers' recommendations.

Any spare parts used should be purchased from the original Manufacturer and repairs should be carried out by the Manufacturer or under his supervision, in order that the item remains in conformance with the certification documents.


The Certification Process

All Electrical Equipment, intended for use in a Potentially Explosive Atmosphere, should be certified as suitable for such use.

The methods of obtaining certification differ in detail, see below, between each certifying body or group of bodies (e.g. CENELEC). Basically this process consists of supplying a representative sample of the equipment along with a set of drawings to a recognised test/certification body e.g. BASEEFA who in turn test the equipment against a recognised Standard e.g. EN50018 and issue a Certificate. The user of the equipment can then refer to this Certificate to enable him to safely put the item into service in a zone appropriate to the Certification.

European Practice – after 1st July 2003

After the above date the ATEX Directive comes into force throughout the EEC. This becomes a mandatory requirement for all equipment intended for use in a hazardous area. The fundamental difference between current practice and ATEX certification is that ATEX addresses the essential safety requirements for hazardous area equipment and uses Standards as part of the method of conforming to these. Amongst other documentation required by certifying authorities will be Technical Manuals in order that the user is informed of installation methods etc.

ALL EQUIPMENT, BOTH ELECTRICAL AND MECHANICAL, INTENDED TO BE PUT INTO SERVICE WITHIN THE EEC AFTER 1ST July 2003, WILL HAVE TO HAVE BEEN CERTIFIED IN ACCORDANCE WITH THE ATEX DIRECTIVE.

In practice this means re-certification of all currently certified electrical equipment.

MEDC have started this process and all relevant equipment will be covered by the implementation date of 1st July 2003.

It should be noted also that MECHANICAL equipment is covered by the ATEX Directive so for the first time items such as gearboxes will have to carry ATEX certification.

The equipment coding will be as the current practice plus an additional code as follows:

ExII2G i.e.

Ex – Explosion proof in accordance with ATEX.

II – Group II surface industries.

2 – category 2 equipment (suitable
.....for use in Zone 1) note:

Category 1 is suitable for Zone 0.
Category 3 is suitable for Zone 2.

G – suitable for atmospheres containing gas ( D is suitable for atmospheres containing dusts).

Equipment will be CE marked when certified to ATEX.

European Practice – Current – until 30th June 2003

The method is basically as above. In addition all electrical equipment intended for use in the European Economic Community (EEC) must comply with Electromagnetic Compatibility regulations (EMC) and manufacturers must issue, on request, an EC Declaration of Conformity in accordance with the EMC regulations.

When certified, an item of equipment and its' certificate, carry a code e.g. EExdIIBT4. This can be broken down as follows:

E – European certificate in accordance with harmonised standards

Ex – Explosion-proof electrical equipment

d – flameproof enclosure type of protection

II – Group II surface industries

B – gas group B

T4 – temperature class T4 (135 degrees centigrade surface temperature).

North American Practice

Sample equipment and supporting documentation are submitted to the appropriate authority e.g. .U.L., F.M., C.S.A.

The equipment is tested in accordance with relevant standards for explosion protection and also for general electrical requirements e.g. light fittings.

After successful testing a listing is issued allowing the manufacturer to place the product on the market.

The product is marked with the certification details such as the gas groups A,B,C,D the area of use e.g. Class 1 Division 1


World-wide Certification

Most countries outside Europe or North America use the IEC Standards as a basis for their own national standards.

The Russian Federation certifies equipment to GOST standards, these closely follow CENELEC practice.

There is a scheme in place which will when fully adopted allow for internationally recognised certification to become a reality, this is the IEC EX SCHEME. This uses the IEC standards and IEC recognised test and certification bodies to issue mutually recognised test reports and certificates. The scheme is in its infancy and its level of success cannot yet be measured.


Ingress Protection

2 digits are used to denote the level of ingress protection that a piece of apparatus enjoys :–
(The first digit denotes the level of protection against solid objects and the second against liquids)

.Solids.Liquids
0No protection.

0No protection.

1Protected against solid objects
up to 50mm, e.g. hands.
1Protected against vertically falling
drops of water.
2Protected against solid objects
up to 12mm, e.g. fingers.
2Protected against water spray up
to 15 degrees from vertical.
3Protected against solid objects
up to 2.5mm, e.g. tools.
3Protected against water spray up to
60 degrees from vertical.
4Protected against solid objects
over 1mm, e.g. wires.
4Protected against water sprays from
all directions.
5Protected against dusts.
(No harmful deposits).
5Protected against water jets from
all directions.
6Totally protected against dust.

6Protected against strong water jets
from all directions, e.g. Offshore.
..7Protected against immersion between
15cm and 1m in depth.
8Protected against long immersion
under pressure.

North American practice is to use NEMA standards to describe ingress protection, i.e.:

NEMA 3 is similar to IP 54
NEMA 4 is similar to IP 55
NEMA 4x is similar to IP 56
NEMA 6 is similar to IP 67


© MEDC 2003
Sunday, July 4 110

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