Page • History and Growth of Chlorine ....................2 • Production Process ......................................3 • Characteristics..............................................4 • Chlorine Containers......................................4 Cylinders ..................................................5 Ton Containers .........................................8 Tank Cars ...............................................11 Cargo Tank Trucks .................................14 • Handling Equipment ...................................15 • Safety and Emergency Information ............17 • Technical Data ............................................20 1 of 32 OxyChem Chlorine Handbook Foreword This handbook outlines the methods for handling, storing, and using chlorine. It also includes information on the manufacture and physical properties of chlorine. Additional information and contacts can be found on the internet at www.oxychem.com Occidental Chemical Corporation Basic Chemicals Group Occidental Tower 5005 LBJ Freeway Dallas, Texas 75244 THE INFORMATION PRESENTED HEREIN WAS PREPARED BY TECHNICAL PERSONNEL AND IS TRUE AND ACCURATE TO THE BEST OF OUR KNOWLEDGE. OXYCHEM DOES NOT MAKE ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, EXPRESS OR IMPLIED, REGARDING PERFORMANCE, STABILITY OR ANY OTHER CHARACTERISTIC. THE INFORMATION CONTAINED HEREIN IS NOT TO BE CONSTRUED AS AN EXPRESS WARRANTY CONCERNING THE PERFORMANCE, STABILITY OR ANY OTHER CHARACTERISTIC OF ANY OXY- CHEM PRODUCT. THIS INFORMATION IS NOT INTENDED TO BE ALL-INCLUSIVE AS TO MANNER OR CONDITIONS OF USE. HANDLING, STOR- AGE, DISPOSAL AND OTHER ACTIVITIES MAY INVOLVE OTHER OR ADDITIONAL LEGAL, SAFETY OR PERFORMANCE CONSIDERATIONS. WHILE OUR TECHNICAL PERSONNEL WILL RESPOND TO ANY QUESTIONS REGARDING SAFE HANDLING AND USE PROCEDURES, SAFE HANDLING AND USE REMAINS THE RESPONSIBILITY OF THE CUSTOMER. NO SUGGESTIONS FOR USE ARE INTENDED AS, AND NOTHING HEREIN SHALL BE CONSTRUED AS A RECOMMENDATION TO INFRINGE ANY EXISTING PATENT OR TO VIOLATE ANY FEDERAL, STATE OR LOCAL LAW. Occidental Chemical Corporation 11/2006 Cl 35.453 17 Chlorine 1, 3, 5, 7 + - 239.1 172.16 3.17 [Ne]3s 2 p 5
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Page
• History and Growth of Chlorine ....................2
• Production Process ......................................3
ForewordThis handbook outlines the methods for handling,
storing, and using chlorine. It also includes informationon the manufacture and physical properties of chlorine.
Additional information and contacts can be foundon the internet at www.oxychem.com
Occidental Chemical CorporationBasic Chemicals GroupOccidental Tower5005 LBJ FreewayDallas, Texas 75244
THE INFORMATION PRESENTED HEREIN WAS PREPARED BY TECHNICAL PERSONNEL AND IS TRUE AND ACCURATE TO THE BEST OF OURKNOWLEDGE. OXYCHEM DOES NOT MAKE ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, EXPRESS ORIMPLIED, REGARDING PERFORMANCE, STABILITY OR ANY OTHER CHARACTERISTIC. THE INFORMATION CONTAINED HEREIN IS NOT TO BECONSTRUED AS AN EXPRESS WARRANTY CONCERNING THE PERFORMANCE, STABILITY OR ANY OTHER CHARACTERISTIC OF ANY OXY-CHEM PRODUCT. THIS INFORMATION IS NOT INTENDED TO BE ALL-INCLUSIVE AS TO MANNER OR CONDITIONS OF USE. HANDLING, STOR-AGE, DISPOSAL AND OTHER ACTIVITIES MAY INVOLVE OTHER OR ADDITIONAL LEGAL, SAFETY OR PERFORMANCE CONSIDERATIONS. WHILEOUR TECHNICAL PERSONNEL WILL RESPOND TO ANY QUESTIONS REGARDING SAFE HANDLING AND USE PROCEDURES, SAFE HANDLINGAND USE REMAINS THE RESPONSIBILITY OF THE CUSTOMER. NO SUGGESTIONS FOR USE ARE INTENDED AS, AND NOTHING HEREIN SHALLBE CONSTRUED AS A RECOMMENDATION TO INFRINGE ANY EXISTING PATENT OR TO VIOLATE ANY FEDERAL, STATE OR LOCAL LAW.
The earliest annals of chemistrymention chlorine compounds. In 77A.D., Pliny the Elder published oneof the first practical collections ofchemical reactions. His formula forgold purification generated chlorineas a by-product in the form ofhydrogen chloride. But more than800 years passed before writtenrecords showed that the Arabs hadlearned to react chlorine with waterto produce hydrochloric acid.
Around 1200 A. D., alchemistsdiscovered that a mixture ofhydrochloric and nitric acids dis-solved gold. This procedure gener-ates chlorine, but there is no recordthat a heavy greenish gas wasevolved. In 1630, Belgian JeanBaptiste van Helmont wrote of a“salt gas” that we know containedchlorine, but it wasn’t until 1774 thatSwedish apothecary, Carl WilhelmScheele, generated, collected, andstudied chlorine as an end in itself.
Even Scheele’s discovery wasnearly accidental. He collected chlo-rine out of simple curiosity. Perhapshe too would have treated the gascasually if he hadn’t, on someimpulse, placed some leaves andflowers into a bottle of chlorine.Within minutes the plants hadturned white, and man had the firsthistorical record of the bleachingaction of chlorine.
Scheele’s discovery came whenboth modern chemistry and theindustrial revolution were takingtheir first halting steps down pathsthat would soon change the courseof history. Antoine Lavoisier, thefather of modern chemistry, tooknote of Scheele’s work and quicklybecame embroiled in a controversyover whether chlorine was an ele-ment or a compound. Meanwhile,textile producers in the French townof Javelle heard of the bleachingaction of this gas, and in 1789 bub-bled it through a potash solutionproducing eau de Javelle, JavelleWater, the first commercial liquidchlorine bleach.
The eruption of the French Revo-lution cut short the intellectual fer-ment begun by Lavoisier and hisfollowers. Lavoisier himself wasguillotined in 1793, but his chem-istry had crossed the English Chan-nel. Once again, scientific curiosityparalleled commercial necessity.Humphry Davy, the English fatherof electrolysis, demonstrated thatchlorine was an element with prop-erties useful to Britain’s rapidlyexpanding textile and paper indus-tries.
In the 1830’s Michael Faraday,Davy’s lab assistant, produced adefinitive work on both the elec-trolytic generation of chlorine andthe ease of its liquefaction. In 1851,Charles Watt obtained the firstEnglish patent for an electrolyticchlorine production cell.
Through the 1880’s and 1890’sproducers in Germany, England,Canada, and the United Statesrefined chlorine technology. Around1890, German producers learnedthat, while wet liquid chlorine wasalmost impossible to package,removal of all water allowed safeshipment in ordinary iron or steelpressure vessels.
By the early 1900’s, chlorine wasproduced in mercury anddiaphragm electrolytic cells andshipped in liquid form as a matter ofcourse. A modern chlorine industryhad formed. By 1913, the first per-manent liquid chlorine water purifi-cation system had been installed inPhiladelphia. The following year,Altoona, Pennsylvania, became thefirst city to treat sewage with liquidchlorine.
World War I brought added impe-tus to North American chlorine pro-duction. Submarine warfare practi-cally eliminated imports ofchemicals from Europe at a timewhen markets for many chemicals,including chlorine, were growingrapidly. By the end of the war, theUnited States had a large and firmlyentrenched domestic chlorineindustry.
In the 1930’s, the world’s chemi-cal industry erupted in a period ofextraordinary growth that still con-tinues. Bleaching properties of chlo-rine became just one of its majoruses. Its disinfecting propertiesremained vital to health, butbecame a minor market for a chem-ical that would soon affect almostevery human activity.
Today, we use chlorine as a rawmaterial in the manufacture ofpolyvinyl chloride, a plastic used infabricating flooring, pipe, wallpaper,clothing, furniture, and a wide rangeof household products. . We treatour illnesses with complex drugsand spray our crops with insecti-cides, herbicides, and fungicideswhich contain chlorine as part oftheir basic structure. Chlorinatedchemicals also enable us to refrig-erate and freeze our food, cool ourhomes, offices and cars, and eveninsulate our buildings from the heatand cold.
One of the most important uses ofchlorine is helping produce chemi-cals that contain no chlorine at all.Chlorine and chlorine chemicalshelp promote reactions that pro-duce chemicals for antifreeze, tex-tile lubricants, fabric softeners,book-binding pastes, solvents forlacquers, brake fluids, polyesterfibers, and a host of other products.
3 of 32ProductionProcess
The basic raw material for theprocess, salt, comes from eithermines or underground wells. Minedsalt is dissolved with water to formraw brine. In other cases, water ispumped into salt deposits, formingbrine in the earth that is tapped anddrawn off from the resulting brinewell.
Raw brine contains impurities thatinterfere with chlorine-caustic pro-duction. They are removed bychemical treatment, settling, and fil-tration. The purified brine ispumped to the cell room. The cellroom contains one of three types ofelectrolytic cells for decomposing
ChlorineProcess
brine into chlorine, caustic soda,and hydrogen. These three celltypes are diaphragm, membrane, ormercury cells.
The chlorine that leaves the cell ishot and wet, and therefore very cor-rosive. It must be cooled and driedbefore it can be processed in ordi-nary steel equipment. In addition,the chlorine stream is contaminatedwith air, hydrogen, and some car-bon dioxide (due to small amountsof carbon bearing chemicals in thebrine).
Once the chlorine stream iscooled and dried, compressors andrefrigeration machines are used toliquefy the gas. Chlorine is mosteasily handled as a liquid in special-ly designed pressure containers.
Any gaseous contaminants in thechlorine stream are removed. Smallamounts of chlorine mixed withthem are nearly completely recov-ered. The recovered chlorine isthen returned to the liquefactionprocess.
Raw Brine Production
ChlorineCooling and
Drying
Chlorine-Caustic Cell
Room
ChlorineCompressors
ChlorineLiquefiers
ChlorineStorage and
Shipping
CausticSolutionStorage
CausticPurification
Salt RemovalCentrifuges (forDiaphragm), Fil-
ters, and Coolers
Caustic Storageand Shipping
Terminal
Caustic SolutionEvaporation (forDiaphragm and
Membrane)
Use as Fuel orSale
Hydrogen Processing
ChlorineRecovery
Brine Purification
Brine Resaturation
Hydrogen
4 of 32 CharacteristicsChlorine, at ordinary conditions of
temperature and pressure, is agreenish-yellow gas with a pungentand irritating odor. Since chlorine isvery active chemically, it is found innature only in combination withother elements. Sodium chloride,for example, is widely and abun-dantly distributed in nature and con-stitutes the chief source of chlorine.Because gaseous chlorine isapproximately two-and-one-halftimes as heavy as air, it is slow todiffuse into the air. It tends to accu-mulate in low places.
Gaseous chlorine can be liquefiedby the application of pressure atreduced temperatures to form aclear, amber-colored liquid. Liquidchlorine is approximately one-and-one-half times as heavy as water.
In the presence of moisture, bothgaseous and liquid chlorine areextremely corrosive to commonmetals of construction. At low pres-sures, wet chlorine can be handledin equipment made of glass, chemi-cal stoneware, titanium, and certainplastics. Installations employing wet
Chlorine is an excellent oxidizingagent which accounts for itswidespread use as a bleachingagent. Liquid and gaseous chlorineare nonflammable and will not sup-port combustion in the normalsense. However, chlorine will sup-port the combustion of certainmaterials under special conditions.
Dry chlorine has an extremelyhigh affinity for moisture. Regard-less of the environmental conditionsof temperature and humidity, allopen ends of chlorine pipelinesshould be sealed with rubber stop-pers or some type of moisture-tightclosure when not in use. An openend of a chlorine delivery line will,within a time interval of only a fewminutes, pick up sufficient moisturefrom the atmosphere to causesevere corrosion.
chlorine require special care andrecommendations can be madeonly after a thorough and carefulinvestigation. Platinum, tantalum,and titanium are some of the metalsresistant to moist chlorine.
Dry chlorine, both gaseous andliquid, can be handled safely inequipment fabricated from iron,steel, certain stainless steels,Monel metal, nickel, copper, brass,bronze, and lead. These metals arenot aggressively attacked by drychlorine but the slightest trace ofmoisture will cause severe corro-sion. However, dry chlorine attacksmetals at elevated temperatures.Chlorine reacts with carbon steel atelevated temperatures. Operationsabove 250°F should be avoided.
Since chlorine boils at about-30°F, under certain conditions itcan embrittle ordinary carbonsteels. If temperatures below -20°Fare expected to occur, special car-bon steels, or other materials ofconstruction should be considered.
ChlorineContainers
Chlorine is supplied in packagesof varying sizes according to therequirements of the customer.Cylinders with a 100 or 150 poundcapacity are available to customersneeding small quantities. Ton con-tainers (2000 lbs. net) can be sup-plied to consumers requiring inter-mediate tonnage. Containers ofthese sizes are supplied by inde-pendent distributors (Repackagers)and not by OxyChem.
limited use and will be phased outof service after 2002.
All chlorine containers and fittingsare of a type approved by TheChlorine Institute, Inc. and mustcomply with the specifications andregulations of the DOT. MostRepackagers maintain facilities forthe inspection, cleaning, testing,and filling of these containers.
Additionally, chlorine cargo tanktrucks with a 15 to 20 ton capacityare in limited use and only availablefrom certain Repackagers.
Receipt of chlorine by tank carrequires special handling and com-pliance with the Department ofTransportation (DOT) HazardousMaterials Regulations, CFR Title49, Tank cars are supplied by Oxy-Chem and are available in 90 toncapacities. 55 ton tank cars are in
seamless steel construction. Cross-sectional drawings of 100-poundand 150-pound cylinders are shownin Figure 1. Cylinders are fitted withvalves in compliance with the speci-fications and regulations of the DOTand approved by The Chlorine Insti-tute, Inc. The U.S. DOT (or Canadi-an equivalent) specification num-ber, serial number, identifyingsymbol, original tare weight, inspec-tor’s official mark, and date ofhydrostatic is stamped on the metal
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Figure 1 - Cylinder
101/2"
81/2"
54"Average
50"Average
54"Average
50"Average
100 Pound Cylinder150 Pound Cylinder
Figure 2 - Cylinder Valve
47/8"
21/4"
FusiblePlug
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3/8" Square
Monel Metal Stem
Packing Nut
Packing Gland
Valve Packing
Neck Ring
3/4" SpecialStraight Thread
Outlet Cap
Valve Body
3/4" StandardPipe Thread
3/8" I. D.
Gasket
near the cylinder neck. Usually theowner’s name or symbol isstamped or embossed in the samearea. To mar or deface these mark-ings is illegal.
Each cylinder is fitted with a capto protect the valve mechanism. Itmust be kept in place whenever thecylinder is not in actual service. Across-sectional drawing of a chlo-rine cylinder valve is shown in Fig-ure 2.
The outlet threads of a chlorinecylinder valve are not standard pipethreads. For this reason, a specialclamp and adapter, as shown inFigure 3, is suggested. The use ofthe clamp and adapter affordsgreater convenience for the con-sumer and protects the cylindervalve from excessive wear.
The chlorine cylinder valve isequipped with a fusible metal plugwhich is a safety device designed tomelt at about 158°F. This safetyplug protects the chlorine cylinderagainst excessive pressure, bymelting and allowing the contents ofthe cylinder to escape when
exposed to high temperature. Thefusible metal plug is located belowthe valve seat and cannot be con-trolled by the valve. The fusiblemetal plug should not be tamperedwith under any circumstances.
No wrench other than the oneshown in Figure 3 should be usedto open or close chlorine cylindervalves. Use of another wrench maydamage the valve stem and makethe valve difficult to close.
6 of 32Storage ofCylinders
Store cylinders of liquid chlorinein a cool place away from steampipes or other sources of heat.
Store cylinders, full or empty, withtheir valve outlet caps and valveprotective caps in place.
Store all cylinders of liquid chlo-rine in a location which is protectedfrom direct sunlight and from damp-ness.
Do not store cylinders where it ispossible for leaking vapors to entera ventilating system.
Store all cylinders in a verticalposition.
Store cylinders so that the oldestshipments of cylinders are used
first. Valve packing may hardenwith prolonged storage, causingleaks when the cylinders are used.
Storage areas should be keptclean so that accumulated trashdoes not present a fire hazard.
1/4"
Figure 3 - Valve Adapter and Clamp
3/4" Pipe Thread
Adapter for Pipe
17/32"
11/4"
3/4"
5/16"
���Valve Body
Clamp
Adapter
Tube
Lead Gasket
Cylinder Wrench
Antimony-lead
Gasket
7 of 32Handling andUse of Cylinders
It is illegal to ship a leaking chlo-rine cylinder or a chlorine contain-ing cylinder which has beenexposed to fire. Consult your chlo-rine supplier for advice under suchcircumstances.
If a chlorine cylinder or its valve isfound out of order, notify the distrib-utor from whom the chlorine waspurchased, giving the cylinder num-ber and the nature of the damage.
Handle all chlorine cylinders withextreme care. Do not drop cylindersor allow them to strike any objectwith force. Do not apply heat tochlorine cylinders or their valves.
Operate chlorine cylinder valvesonly with the wrenches shown inFigure 3. Under no circumstancesuse a pipe wrench or any wrenchlonger than six inches. Always usethe correct special clamps andadapters as shown in Figure 3.
Use valves, gauges, regulators,and fittings which have beenapproved for chlorine service. Ordi-nary devices are not suitable.
The cylinder must be in an uprightposition to remove chlorine as agas. If liquid chlorine is to be with-drawn from a cylinder, the cylinder
must be inverted and clampedsecurely on a rack set at an angleof about 60° to the horizontal.
Use flexible connections betweencylinders and piping systems (Fig-ure 4). Copper tubing capable ofwithstanding pressures up to 400pounds per square inch is satisfac-tory for dry chlorine.
Close valves on chlorine cylinderswhen chlorine is not being with-drawn in order to prevent moist airor foreign substances from enteringthe cylinder. It is dangerous to allowany chlorine cylinder, which hasemptied its contents into water oranother liquid, to remain connectedwith the process line. In such casesliquid could be sucked back into thecylinder causing danger to the oper-ator and damage to the cylinder.
Replace outlet cap and valve pro-tective cap as soon as the cylinderis disconnected.
Do not alter or repair chlorinecylinders or their valves.
Leaks around the valve stem areusually corrected by tightening thepacking nut in a clockwise direction.All threads on all chlorine valvesare right-hand threads.
Provide suitable hand trucks formoving cylinders. These should beproperly balanced and have aclamp support at least two-thirds ofthe way up the cylinder. If chlorinecylinders are to be lifted, provide asuitable sling. Do not use a chain,rope, or magnetic device. Do not liftcylinders by their valve protectivecaps because they are notdesigned for this purpose.
To monitor the consumption ofchlorine at any given time, place thecylinder on a scale. The differencein weight between measurementswill equal the quantity consumed.
Figure 4 - Flexible Tubing Connector for Ton Containers and Cylinders
Cylinder Valve Adapter
17/32"
19/16"
1/4" 3/4"
5/16"
Alternate Adapter for Pipe Connection
21/4"
1/4" Pipe Thread
Brass Adapters
Silver Solder
8 of 32TonContainers
The ton containers for liquid chlo-rine are constructed of steel. Likethe cylinders, they are fitted withvalves approved by The ChlorineInstitute, Inc. and in compliancewith the specifications and regula-tions of the DOT.
The average ton container (Fig-ure 5) is about 30 inches in outsidediameter and about 82 inches inlength. Average tare weight is about1500 pounds, average gross weightis about 3500 pounds, leaving 2000pounds net weight.
Each end of a ton container isconcave. The sides are crimpedinward over the ends to formchimes that provide suitable gripsfor hooks used in handling. Eachcontainer is equipped with twovalves, both of which are located atthe same end, near the center. Thevalves are connected to eductionpipes as shown in Figure 5. Withthe container placed horizontally sothat the two valves are in verticalalignment, the lower valve will deliv-er liquid chlorine. Gaseous chlorinefrom above the liquid level will flowthrough the upper valve. Pointed
arrows on the valve end of a toncontainer indicate the position ofthe two valves. These arrows arevisible when the protective bonnetis in place, allowing proper position-ing of a ton container before remov-ing the bonnet. There are six fusiblemetal plugs in each ton container,three on each end. The fusiblemetal in these plugs melts at about158°F. The melting plug preventsbuild up of excessive pressurewhen exposed to high temperature.The fusible metal plugs should notbe tampered with under any circum-stances. The container number,dates of hydrostatic tests, andwater capacity are stamped in themetal of an unpainted portion of the chime at the valve end ofeach ton container. To mar ordeface these markings is illegal.Thetare weight of each ton container isstenciled on the end opposite thevalves.
The ton container valve is thesame as the cylinder valve exceptthat it has a larger discharge portand no fusible metal plug. A crosssection of the ton container valve isshown in Figure 6. The outletthreads of a ton container valve arenot standard pipe threads. For thatreason, a special clamp andadapter shown in Figure 3, are sug-gested.
The use of the clamp and adapteraffords greater convenience for theconsumer and protects the ton con-tainer valve from excessive wear.
9 of 32Storage ofTon ContainersStorage
Store ton containers of liquidchlorine in a cool place, away fromsteam pipes or other sources ofheat.
Store all ton containers, full orempty, with their valve outlet capsand valve protective bonnets inplace.
Store all ton containers of liquidchlorine in a location which is pro-tected from direct sunlight and fromdampness.
Do not store ton containers of liq-uid chlorine near flammable materi-als.
Store ton containers where it isnot possible for leaking vapors toenter a ventilating system.
Store ton containers in a horizon-tal position on a level rack. Keepthem on the same level. Do notstack ton cylinders to avoid the pos-sibility of the one at the bottomdeveloping a leak and being difficultto remove.
Figure 5 - Ton Container
Three Fusible Plugsat Each End
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Gas Eduction Pipe
LiquidEduction Pipe
Upper Gas ValveLower Liquid Valve
Valve Bonnet
6'91/2"
2'6"
Detail of Fusible Plug
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Figure 7 - Ton Container Lifting Beam
Only the wrench shown in Figure 3is to be used to open or close a toncontainer valve. Clamps, adapters,and valve wrenches are availablefrom your chlorine distributor.
A suitable hoist equipped with alifting beam as shown in Figure 7 isrequired to remove or replace thecontainers.
10 of 32
Handling andUse ofTon Containers
Shipping a leaking chlorinecontainer or one, partially or fullyloaded, which has been exposedto fire is illegal. Consult your dis-tributor for advice under such cir-cumstances.
If a ton container or its valvesare found out of order, notify thedistributor from whom the chlo-rine was purchased, giving thecontainer number and nature ofthe damage.
Handle all chlorine ton contain-ers with extreme care. Do notdrop ton containers or allow themto strike any object with force. Donot apply heat to ton containersor their valves.
Ton container valves should beoperated only with wrenches asshown in Figure 3. Under no cir-cumstances use a pipe wrench orany wrench longer than six inch-es. Always use special clampsand adapters. (See Figure 3.)
Use valves, gauges, regulators,and fittings which have beenapproved for chlorine service.Ordinary devices are not suitable.
Use flexible connections betweenton containers and piping systems.(See Figure 4.) Copper tubingcapable of withstanding pressuresof 400 pounds per square inch issatisfactory for dry chlorine. A typi-cal installation is shown in Figure 8.
Use the lower valve to withdrawliquid chlorine and the upper valveto remove chlorine gas.
Close valves on ton containerswhen chlorine is not being with-drawn to prevent moist air or for-eign substances from entering thecontainer. It is dangerous to allowany chlorine container, which hasemptied its contents into water orother liquid, to remain connectedwith the process line. In suchcases, liquid could be sucked backinto the container causing danger tothe operator and damage to thecontainer.
Replace outlet caps and valveprotective bonnets as soon as thecontainers are disconnected.
Always have an attendant presentwhen chlorine is being withdrawnfrom a ton container.
Do not alter or repair ton contain-ers or their valves.
Leaks around the valve stem usu-ally can be corrected by tighteningthe packing nut in a clockwisedirection. All threads on all chlorinevalves are right-hand threads.
Place a ton container on a scaleas its contents are removed todetermine the quantity of chlorine inthe container at any time.
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Figure 8 - Typical Construction
Scale
Ton Chlorine Container
Liquid Chlorineto Process
or
Liquid Chlorineto Vaporizer
Liquid Chlorinefrom Ton Container
Ton Container Valve and Clamp
Connection
Flexible Connection
Tubing
Vaporizer
Pressure Gauge
Barometric Vacuum Break Loop
(Min. Ht. 34 Ft.)
Chlorine Gasto Process
Water Overflow
Control Valve
Hot Water
11 of 32Tank CarsOxyChem’s large fleet of tank
cars comply with all specificationsand regulations of the DOT. Liquidchlorine is supplied in tank cars withcapacities of 55 tons and 90 tons.
The tank of most tank cars is offusion welded steel construction,built according to DOT specifica-tions 105A300W and 105A500W.The tank is provided with a thickcovering of insulating materialwhich in turn is protected by a steeljacket. The only opening in the tankis in the dome which contains all ofthe valves on the tank. (See Fig-ures 9 and 10.)
The two angle valves parallel tothe length of the tank car deliver liq-uid chlorine. The liquid valves areconnected to eduction pipes whichare equipped with excess-flowvalves. The excess-flow valves aredesigned to stop the flow of liquidchlorine if the delivery rate exceeds7,000 pounds/hour for a 55 toncapacity car or 15,000 pounds/hourfor a 90 ton car. The angle valvemust be fully opened to allow theexcess-flow valve to function incase of a ruptured delivery line.(See Figure 11.)
The two angle valves at rightangles to the longitudinal axis of thetank car will deliver gaseous chlo-rine or they can be used to applydry air or nitrogen padding.
The safety valve is located at thecenter of the dome, (Figure 9, ValveNumber 5). On DOT 105A300Wtanks, it is designed to initiallyrelieve at a pressure of 225 psig.Following the initial relief, the valvefunctions as a regular spring loadedvalve set at 213 psig. On a105A500W tank, the safety valve isdesigned to initially relieve at apressure of 375 psig and then itoperates as a regular spring loadedvalve set to discharge at 360 psig.Safety valves on chlorine tank carsmust never be disturbed or tam-pered with under any circum-stances.
The outlet of each angle valve ona tank car has one-inch standardtapered female pipe threads. Thisoutlet is protected by a one-inchpipe plug which must be kept inplace whenever the valve is not inuse.
Each time a tank car is returnedto OxyChem, it is subjected to a rig-orous inspection. Any damagedtank car is immediately removedfrom service until such time asrepairs can be made.
When the angle valves areremoved, they are dismantled, com-pletely reconditioned, and subjectedto a static test at a pressure fargreater than a normal working pres-sure. The excess-flow valves areinspected and cleaned at the sametime. Safety valves are removed,reconditioned, and tested every twoyears.
Figure 9 - Standard Arrangement of Valves on Single Unit Tank Car
Brake Endof Car
No. 2Gas Valve
No. 3Liquid Valve
No. 1Liquid Valve
No. 4Gas Valve
No. 5Safety Valve
Figure 10 - Single-Unit Tank Car Valve Figure 11 - Excess Flow Valve with Removable Seat
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Note: Figures 9 and 10 showtypical installation for the ACFangle valve.
12 of 32Handling andUse of Tank Cars
Single-unit tank cars must beunloaded only on the consumer’sprotected private track.
When a tank car of chlorine isplaced on a private siding for
unloading, the brakes must be setand the wheels blocked. The follow-ing precautions are required byDOT Hazardous Materials Regula-tion, CFR Title 49, Paragraph
174.67, governing the transporta-tion of hazardous materials: “Cau-tion” signs must be placed in such aposition on the track or car to warnpersons approaching the car from
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13 of 32Handling andUse of Tank Cars
the open end or ends of the sidingand must be left up until after thecar is unloaded and disconnectedfrom the discharge connection.Signs must be of metal, at least 12by 15 inches in size and bear thewords “STOP—Tank Car Connect-ed” or “STOP—Men at Work.” Theword “STOP” must be in letters atleast 4 inches high and the otherwords in letters at least 2 incheshigh. The letters must be white on ablue background.
Tank cars must be protected by aderail at the switch end or ends of asiding.
Shipping a leaking or defectivetank car containing any chlorine isillegal. If a tank car is defective, callyour supplier. OxyChem’s 24 houremergency number is 800/733-3665.
Use a flexible metal connectionfor unloading chlorine as outlined inThe Chlorine Institute, Inc. Pam-phlet No. 6, DWG No. 118. A typicalinstallation is shown in the diagramin Figure 12.
Opening a liquid chlorine valvetoo rapidly could cause the excess-flow valve to function and stop theflow of liquid chlorine. The excess-flow valve can be unchecked byclosing the chlorine valve complete-ly and waiting until a noticeableclick is heard, indicating that themetal ball has fallen back intoplace.
In many chlorine handling sys-tems, additional pressure is neces-sary for unloading at a normal oraccelerated rate. Under these con-ditions, dry air (dew point of -40°F)must be used.* A separate plant air
drying system is needed for thisoperation.
Safe padding pressure limits aredefined by the setting of the pres-sure relief valve and the tempera-ture of the liquid chlorine. Paddingpressure limits for chlorine tankcars can be found in the The Chlo-rine Institute, Inc., Drawing # 201.
For additional information on thehandling and use of tank cars referto The Chlorine Institute, Inc., Pam-phlet # 66.
* Dry nitrogen may also be usedin most cases.
14 of 32CargoTank Trucks
DOT issued CFR Title 49, givesthe MC331 specification for cargotank trucks authorized for chlorineuse in the United States and Cana-da.
Chlorine cargo tank trucks meet-ing DOT Specification MC331 orMC330 have an approximatecapacity of 15 to 20 tons. The onlyopening in a chlorine cargo tanktruck is in the dome which containsall of the required valves. The twoangle valves parallel to the length ofthe tank will deliver liquid chlorine.The liquid valves are connected toeduction pipes which are equippedwith excess-flow valves. Theexcess-flow valves are designed tostop the flow of liquid chlorine if thedelivery rate exceeds 7,000 poundsper hour.
The two angle valves at rightangles to the longitudinal axis of thetank will deliver gaseous chlorine.They are also equipped withexcess-flow valves, but of a differ-ent design.
The outlet of each angle valve ona chlorine cargo tank truck has one-inch standard tapered female pipethreads. This outlet is protected bya one-inch pipe plug which shouldbe kept in place whenever the valveis not in use.
The safety valve is located at thecenter of the dome, between theangle valves. It is designed to ini-tially relieve at a pressure of 225psig. Subsequent to relief, the valvefunctions as a regular spring loadedvalve set at 213 psig.
Handling and Use of ChlorineCargo Tank Trucks
In general, chlorine can beshipped in cargo tank trucks only ifthe contents are to be unloaded atone unloading point. For this rea-son, Occidental Chemical will assistin any individual study or evaluationto determine if tank truck shipmentsof chlorine are feasible.
Tank Truck Unloading—Air Padding
In many chlorine handling sys-tems, additional pressure is neces-sary for unloading at a normal oraccelerated rate. Under these con-ditions, dry air (dew point of -40°F)must be used.* A separate plant airdrying system is needed for thisoperation.
For additional information onchlorine tank motor vehicles, referto The Chlorine Institute, Inc. Pam-phlet No. 49.
* Dry nitrogen may also be usedin most cases.
15 of 32HandlingEquipment
In general, pipelines for handlingchlorine should be fabricated fromextra-heavy, black-iron pipe. Jointsmust be welded or flanged. Fittingsmust be eliminated wherever possi-ble.
Valves for chlorine service shouldbe constructed of forged steel.Packing for these valves should beeither PTFE or flexible graphite. Foradditional information on valves forchlorine service please consult TheChlorine Institute, Inc., Pamphlet #6.
The use of valves in pipelinesmust balance minimizing accidentalrelease and reducing fugitive emis-sions. Liquid chlorine has a highcoefficient of thermal expansion. Ifliquid chlorine is trapped betweentwo valves, high pressure maydevelop and lead to a rupture of theline or its fittings. Expansion cham-bers, installed at the highest point inthe section may be needed. Expan-sion chambers are fabricated fromextra-heavy pipe and have a capac-ity equal to at least 20 volume per-cent of the protected section ofpipe.
For more information on pipingsystems, consult The Chlorine Insti-tute, Inc., Pamphlets # 6 and 60.
Chlorine VaporizerWhen large amounts of gaseous
chlorine are required for a specificprocess, it is advisable to removethe chlorine from the manufactur-er’s container as a liquid and pass itthrough a vaporizer to convert it toa gas. In this manner much moregaseous chlorine can be sent toprocess than would otherwise bepossible. Rapid removal of gaseouschlorine from a container will coolthe remaining liquid chlorine to apoint where no chlorine vapor willflow into the process. The use of avaporizer supplies sufficient heat tothe liquid chlorine from an outsidesource so that the temperature ofthe chlorine supply remains rela-tively constant. Figure 8 shows atypical installation using a vaporizerto obtain gaseous chlorine from aton container. Figure 12 shows atypical installation using a vaporizerto obtain gaseous chlorine from asingle-unit tank car.
For more information on ChlorineVaporizers, consult The ChlorineInstitute, Inc. Pamphlet No. 9.
Pressure Drop in Liquid Chlorine Lines
Any liquid passing through apipeline suffers a loss in pressuredue to the resistance to flow offeredby the pipeline. A further loss inpressure or head is experiencedwhen the liquid is elevated. Forevery foot in elevation that liquidchlorine is raised, there is a loss inpressure of about 0.635 psi whichshould be added to the pressurelosses due to the resistance of thepiping.
The graph on page 16 shows thecalculated pressure drop for liquidchlorine flowing through SCH 80pipe of various dimensions. Whenvalves and fittings are included inthe piping system, the additionalpressure loss can be readily com-puted by converting the friction lossin the valves and fittings to equiva-lent lengths of straight pipe. Thedata below are taken from CraneCompany Technical Paper No. 409.
Equivalent Length of Pipe in FeetFitting 1" 3/4" 1/2"
Pressure Drop for Liquid ChlorineFlowing in New Steel Pipe
TechnicalData
17 of 32
Safety andEmergencyInformation
All personnel engaged in han-dling chlorine must be thoroughlyinstructed in the necessary precau-tions for the safe handling, storage,and use of chlorine. Carefully studyeverything in this manual.
Read the MSDS before use.Chlorine is a chemical element.
Neither the gas nor the liquid aloneis explosive or flammable. Bothreact chemically with many sub-stances, especially at elevated tem-peratures. The gas is greenish-yel-low in color at high concentrations.It has a penetrating odor, and istwo-and-one-half times as heavy asair. If it escapes from a container orsystem, it will seek the lowest levelin the building or area in which theleak occurs. Training should includethe use of safety equipment andfirst aid procedures.
EMPLOYEE PROTECTIONDo not breathe chlorine vapors.
Chlorine irritates the mucous mem-branes, respiratory tract, and eyes.Smoking can aggravate the respira-tory symptoms which result fromchlorine exposure. Prolonged expo-sure to the gas causes coughing,gagging, and may result in pul-monary edema and death. Individu-als with respiratory problems shouldconsult a physician before workingwith chlorine.
Avoid contact with eyes, skin, andclothing. Gaseous chlorinehydrolyzes in the presence of mois-ture, forming hydrochloric acid,which irritates the eyes and skin.Liquid chlorine removes body heat,freezing exposed skin.
Wash thoroughly after handlingchlorine. Shower, using plenty ofsoap and water.
Safety EquipmentUse goggles, rubber gloves, rub-
ber shoes, hard hat, and a NIOSHapproved respirator with an acidgas cartridge where airborne con-centrations are expected to exceedexposure limits or when symptomshave been observed that are indica-tive of overexposure. It is essentialthat each individual who may beexposed to chlorine carry, at alltimes, a respirator approved for
chlorine use. For re-entry into anemergency area, self-containedbreathing equipment must be used.
EQUIPMENT & EMERGENCY PROCEDURESVentilation
Provide adequate ventilation toreduce the accumulation of liquid orgaseous chlorine in low areas. Insome cases, natural ventilation maybe adequate; in others, artificialventilation, such as forced airthrough a system of ducts, must beprovided. A one to four minute rateof air change is required in anemergency. Precautions must betaken to avoid discharging chlorineinto areas where it can cause dam-age or personal injury.
Eye Wash Fountains and Deluge Showers
Readily accessible eye washfountains and deluge showers mustbe provided in strategic locationswherever chlorine is used. Person-nel should test equipment each daybefore beginning work to ensureadequate water flow.
Emergency Respiratory Protection
Severe exposure to chlorine mayoccur wherever chlorine is handledor used. Therefore, self-containedpositive pressure breathing appara-tus, approved for emergency chlo-rine use, should be located strategi-cally outside chlorine work areasnear entrances and away from con-tamination. Such equipment shallhave a rating of at least 30 minutesuse, and be equipped with a lowpressure warning bell. Any personentering a chlorine emergency areamust be protected by this respirato-ry protective equipment.
Emergency Kits In an emergency involving chlo-
rine cylinders, ton containers, tankcars, or barges, kits are availablewhich can be used to stop leaks.Chlorine emergency kits are main-tained by producers and are locatedstrategically throughout the UnitedStates and Canada. In addition, kitsare available from other chlorine
users and distributors, and the loca-tion of these kits can be found inThe Chlorine Institute, Inc. Pam-phlet No. 35, “Location of ChlorineEmergency Kits.” Obtain a copyand note the nearest source, or pur-chase kit(s) from an approved sup-plier.
OTHER EMERGENCY MEA-SURES
The Chlorine Institute, Inc. wasformed over 50 years ago by chlo-rine producers to promote the safeuse of chlorine and to standardizechlorine handling equipment. TheInstitute also sponsors a mutualassistance program in which trainedteams respond to chlorine emer-gencies on a 24-hour-a-day, 7-day-a-week basis. In the United States,this response program is known asCHLOREP (Chlorine EmergencyPlan). The United States is dividedinto 32 sectors with CHLOREPteams available from 49 plant sites(one to three plant sites in eachsector).
CHLOREP is now affiliated withCHEMTREC (The Chemical Trans-portation Emergency Center) main-tained by the Chemical Manufactur-ers Association (CMA) inWashington, D.C. Assistance canbe summoned by calling eitherCHEMTREC (Toll free 1-800-424-9300) or the appropriate CHLOREPteam.
Canada is divided into ten regionswith teams available from 13 plant
18 of 32
Safety andEmergencyInformation
sites as established by TEAP(Transportation Emergency Assis-tance Plan) of the Canadian Chemi-cal Producers’ Association. InCanada, assistance is available bycalling either the TEAP regionalnumber or the appropriate responseteam.
In both the United States andCanada, these teams provide assis-tance in any chlorine emergencywhether a transportation incident ora problem at the point of usage.Chlorine users must have the tele-phone number of their responseteam(s) readily available for use inchlorine emergency situations.
Chlorine users must acceptresponsibility for taking all properprecautions to prevent accidentswith chlorine. The fact that emer-gency assistance is availableshould not encourage carelessnessin the use of this chemical.
HANDLING AND STORAGE
Store cylinders and ton contain-ers in a dry, ventilated, fire resistantarea separate from metals, organic,or inorganic chemicals. All valvesmust be kept tightly closed until
containers are connected forunloading. Protect from heat anddirect sunlight.
In Case of Fire Chlorine itself will not burn, but it
does act as an oxidizer and sup-ports combustion, even in theabsence of oxygen. Cool the affect-ed containers with large amounts ofwater. Use any other extinguishingmedium appropriate for the sur-rounding fire. All fires liberate toxicgases. Use self-contained breathingapparatus and full protective equip-ment.
LeaksDo not apply water directly on a
chlorine leak. Moisture hydrolyzeschlorine, forming hydrochloric acidwhich attacks the metal, thusenlarging the leak. If a container isleaking chlorine, position the con-tainer so that gas escapes insteadof liquid. The quantity of escapingchlorine is significantly less from agas leak than a liquid leak, sinceone volume of liquid is equal toabout 460 volumes of gas. Evacu-ate the area and keep all personnel
upwind of leaks, preferably on highground. Secure self-containedbreathing apparatus. Shut chlorinesupply off at source.
Water DisposalAbsorb chlorine in an alkaline
solution (caustic soda, soda ash, orhydrated lime) while maintaining anexcess of base at all times (seebelow).* Destroy resultinghypochlorite by adding sodium sul-fite or treating the basic hypochlo-rite at 122°-158°F (50°-70°C) in thepresence of copper, nickel, or iron.Control pH at the discharge tosewer or the receiving water andcomply with all applicable federal,state, and local regulations.
Recommended Alkaline Solutions for Absorbing ChlorineSize of 100% Caustic Soda 100% Soda Ash 100% Hydrated Lime
Chlorine Container Pounds Water Pounds Water Pounds Water(Pounds Net) (gallons) (gallons) (gallons)
* Slurry must be continuously and vigorously agitated if chlorine is to be absorbed 100%.
19 of 32
Safety andEmergencyInformation
FIRST AIDExposure Symptoms
Liquid chlorine is a skin and eye irri-tant. Prolonged contact producesburns. Liquid chlorine slowly vapor-izes to gas in the open atmosphere.At detectable odor levels, the gas willirritate the mucous membranes andrespiratory tract. (Detectable odor lev-els range from 0.3 to 3.0 ppmdepending on the individual.) Withexcessive exposure to chlorine, theindividual exhibits excitement, accom-panied by restlessness, sneezing,and copious salivation. In extremecases, retching, pulmonary edema,and even death may occur.
There are no specific known anti-dotes for chlorine. Effective medicalmanagement is necessary for relief ofsymptoms with proper treatment.Complete recovery normally occurs.Inhalation
If chlorine is inhaled, move the indi-vidual to fresh air. If breathing is diffi-cult, have a trained person administeroxygen. If respiration stops, have atrained person administer artificialrespiration.
Treatment for inhalation must pre-cede first aid given to other bodyareas affected by exposure to chlo-rine.Skin
In case of contact, immediatelyremove the contaminated clothingand shoes. Flush skin with plenty ofwater. Never attempt to neutralize thechlorine with chemicals. Salves andointments should not be appliedunless directed by a physician. Washclothing before re-use. Discard con-taminated nonrubber shoes. GETMEDICAL ATTENTION IMMEDIATE-LYEyes
In case of eye contact, immediatelyflush eyes with a directed stream ofwater (low pressure-high volume) for15 minutes. Forcibly hold eyelidsapart to ensure complete irrigation ofall eye and lid tissues. An eye washfountain is ideal for this type of treat-ment. GET MEDICAL ATTENTIONIMMEDIATELY.
IngestionDue to its physical properties, swal-
lowing liquid chlorine is extremelyunlikely. In such an instance, call aphysician immediately.Notes to Physician
Because there is no known anti-dote for chlorine gas inhalation, treat-ment is symptomatic. The effectiveand immediate relief of symptoms isthe primary goal. Steroid therapy, ifgiven early, has been reported effec-tive in preventing pulmonary edema.EMPLOYEE TRAINING FORSAFE OPERATIONS
Safety in handling chlorinedepends, to a great extent, upon theeffectiveness of employee education,proper safety instructions, effectivesupervision, and the use of properpersonal protective equipment.
Supervisory personnel are respon-sible for providing proper instructionand training of employees. Trainingfor all employees should be conduct-ed periodically, to reinforce correctmethods and to maintain a highdegree of competence in handlingprocedures. All new employees mustbe trained in handling and using chlo-rine before operating equipment.Employees should be thoroughlyfamiliar with the hazards that mayresult from improper handling of chlo-rine. Each employee should knowemergency and first aid measures,and how to use associated equip-ment.
As a minimum, employee trainingshould include the following:A) Instruction with periodic drills
regarding the locations, purpose,limitations, and use of chlorineemergency kits, fire fighting equip-ment, fire alarms, and shutdownequipment such as valves andswitches.
B) Instruction with periodic drillsregarding the locations, purpose,limitations, and use of personalprotective equipment, both normaland emergency.
C) Instruction with periodic drillsregarding the locations, purpose,and use of safety showers, eyebaths, or the closest source ofwater for use in emergencies.
D) Instruction with periodic drills forspecified employees on each workshift/period regarding the locations,purpose, and use of emergencyrespiratory protection and first aidequipment.
E) Instruction on avoiding inhalationof chlorine gas and contact withthe liquid. Emphasis should beplaced on chlorine’s effect on thehuman body at different exposurelevels.
F) Instruction on procedures forreporting all equipment failures tothe proper authority.
G) Instruction on procedures for con-ducting inspections before workingwith equipment, and periodicallyduring operations. This instructionshould include procedures for rec-ognizing leaks and other potential problems.
H) Instruction on the proper actions totake when leaks occur and on pro-cedures for evacuating affectedareas.
20 of 32Technical Data
Physical Properties of Chlorine
Atomic weight: 35.453Boiling point: -34.05°C (-29.29°F)Freezing point: -100.98°C (-149.76°F)Critical temperature: 144.0°C (291.2°F)Critical pressure: 7711 kPa (76.1 atm, 1118 psi)Critical volume: 1.745x10-3m3/kg (0.02796 cu ft/lb)Heat of fusion at the melting point: 6405± 5 J/mol
(38.86 Btu/lb)
Viscosity of Chlorine Gas at 1 Atm
°C cp.-30 0.0112
0 0.0126100 0.0169200 0.021300 0.025
Thermal Conductivity of Chlorine Gas at 1 Atm
°C Btu/(hr-ft-°F)-30 0.0042
0 0.0048100 0.0067200 0.0086300 0.0103
Thermal Conductivity of Liquid Chlorine
°C Btu/(hr-ft-°F)-100 0.1149
0 0.0847100 0.0532144 0.0230
Conversion of Units
Physical Quantity Sl Unit ConversionConcentration kilograms per cubic meter 1 kg/m3 = 0.008345 lbs/galDensity kilograms per cubic meter 1 kg/m3 = 0.062428 lbs/cu ftEnergy joules per kilogram 1 J/kg = 0.000430 Btu/lbEntropy joules per kilogram-Kelvin 1 J/kg-°K = 0.000239 Btu/lb-°FPressure Pascals (Newtons per square meter) 1 Pa = 0.000145 psi
1 Pa = 9.86923x10-6 atmSurface Tension joules per square meter 1 J/m2 = 0.068522 lb(force)/ft
REF: Kapoor, R.M.; Martin, J.J.,Thermodynamic Properties of Chlorine,Engineering Research Institute, University of Michigan, Ann Arbor, Michigan (1957).
22 of 32Technical Data
Thermodynamic Properties of Superheated Chlorinev, volume (cu ft/lb); h, enthalpy (Btu/lb); s, entropy (Btu/lb-°R) Figures in parenthesis under the pressures are the saturation temperaturesBase: h = 0, s = 0 for solid Cl2 at 0°R
t v h s v h s v h s v h s25 2.3717 231.43 0.71759 2.0222 231.25 0.71306 1.7600 231.08 0.70910 1.5559 230.90 0.7055850 2.5034 234.30 0.72336 2.1358 234.14 0.71885 1.8601 233.97 0.71492 1.6456 233.81 0.7114275 2.6343 237.18 0.72889 2.2489 237.03 0.72440 1.9597 236.88 0.72048 1.7348 236.73 0.71701
t v h s v h s v h s v h s50 1.4740 233.65 0.70827 1.2163 233.31 0.70276 1.0321 232.97 0.69803 — — —75 1.5547 236.57 0.71388 1.2846 236.26 0.70841 1.0915 235.95 0.70373 0.9465 235.62 0.69961
REF: Kapoor, R.M.; Martin, J.J.,Thermodynamic Properties of Chlorine,Engineering Research Institute, University of Michigan, Ann Arbor, Michigan (1957).
23 of 32
TechnicalData
24 of 32TechnicalData
Specific Heat (Heat Capacity) of Liquid Chlorine
25 of 32TechnicalData
26 of 32TechnicalData
0
10
20
30
40
50
60
70
80
90
100
110
120
130
140
150
0
10
20
30
40
50
60
70
80
-130 -80 -30 20 70 120 170 220 270 320
-90 -40 10 60 110 160
Hea
t of
Vap
oriz
atio
n, B
TU
/lb.
Hea
t of
Vap
oriz
atio
n, k
cal./
kg.
Temperature, Fahrenheit
Temperature, Centigrade
Latent Heat of Vaporization of Chlorine
27 of 32
0.001
0.010
0.100
0.300
0.12
1.00
10.00
35.94
0.10 1.00 10.00 100.00
0.7 1.0 10.0 100.0 690.0
Sol
ubi
lity
, lbs
./gal
.
Sol
ubi
lity
, kg.
/cu
. met
er
Partial Pressure, psia
Partial Pressure, kPa
Solubility of Chlorine in Water
32°F 50
°F
68°F
86°F
104°
F 122°
F
140°
F
158°
F
176°
F
TechnicalData
28 of 32
0.1
1
10
100
1000
10000
0.7
1.0
10.0
100.0
1000.0
10000.0
69000.0
-130 -80 -30 20 70 120 170 220 270 320
-90 -40 10 60 110 160
Vap
or p
ress
ure,
psi
a
Vap
or p
ress
ure,
kP
a
Temperature, Fahrenheit
Temperature, Centigrade
Vapor Pressure of Saturated Chlorine
TechnicalData
29 of 32TechnicalData
0.00
0.10
0.20
0.30
0.40
0.50
0.60
0.70
0.80
0.90
1.00
1.10
0.00000
0.00005
0.00010
0.00015
0.00020
0.00025
0.00030
0.00035
0.00040
0.00045
0.00050
0.00055
0.00060
0.00065
0.00070
-150 -100 -50 0 50 100 150 200 250
-100 -50 0 50 100
Vis
cosi
ty, C
enti
pois
e
Vis
cosi
ty, l
bs./f
t.-s
ec.
Temperature, Fahrenheit
Temperature, Centigrade
Viscosity of Liquid Chlorine
30 of 32TechnicalData
31 of 32TechnicalData
50
100
150
200
250
27.8
47.8
67.8
87.8
107.8
127.8
-130 -80 -30 20 70 120 170 220 270 320
-90 -40 10 60 110 160
Liq
uid
Ent
halp
y, Δ
H, B
TU
/lb.
Liq
uid
Ent
halp
y, Δ
H, k
cal./
kg.
Temperature, Fahrenheit
Temperature, Centigrade
Enthalpy of Liquid Chlorine
32 of 32 BibliographyKapoor, R.N.; Martin, J.J.“Thermodynamic Properties ofChlorine”Engineering Research Institute,University of Michigan, Ann Arbor,Michigan (1957).
Kirkbride, F.W.in Mellow, J.W.: “Inorganic andTheoretical Chemistry,” Vol. II,Suppl. I, Sect. XIII.John Wiley & Sons Inc., New York(1956).
Laubusch, E.J.in “Chlorine, Its Manufacture, Prop-erties and Uses,” Ch. 3 (Ed.:Sconce, J.S.)ACS Monograph Series No. 154Reinhold Publishing Corp., NewYork (1962).
McBride, B.J.; Heimel, S.; Ehlers,J.G.; Gordon, S.“Thermodynamic Properties to6000°K for 210 Substances Involv-ing the First 18 Elements”NASA SP-3001. Lewis ResearchCenter, Cleveland, Ohio (1963).
McGlashan, M.L.“IUPAC Manual of Symbols andTerminology for PhysiochemicalQuantities and Units”Pure Appl. Chem 21, 1 (1970).
Mussini, T.; Faita, G.in “Encyclopedia of Electrochem-istry of the Elements,”Vol. 1, Ch. 1 (Ed.: Bard, A.J.)Marcel Dekker, Inc., New York(1973).
Stull, D.R.; Prophet, H.“JANAF Thermochemical Tables”2nd Ed.NSRDS – NBS37National Bureau of Standards,Washington, D.C., (1971).
Svehla, R.A.“Estimated Viscosities and ThermalConductivities of Gases at HighTemperatures”NASA Technical Report R-132Lewis Research Center, Cleveland,Ohio (1962).