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HomeMy WebLinkAboutProduct ReviewG � ! r /UI��DER� R wr eJ x (� fi y V ,.It •1 r. d G .•5 T VC4 �'Cr •���t • x din ncprepoxytpnmer �fi 8" dorrre In `blackpp a Ic r Hi e .,� ;� ,Sup'er ureheTGlCpofyest>; topco fr' galvanlzeeel�' "_>,,• � ,�'�.,,.� ,� `, �„ �'R,atent}p ndl[q"form6l3`ted�nnmar.�r;�+����,�,+ 120 r2 000 ,wq ., r• NEW.!, :oat: I II • Dual service options forabove or+underground applications^^ - .•fOptionrtll.ReadyQ.- -ury're d;oxide.'durable'powde�coatingwitlt"61ack Ik . . ? polyefhylemeyAGV(kd ey '@©flon #22, Abdveground)Loption 9ltFi•steel;8" AGUE dome ` ICO All valyes@nd float'gduges are ceWEe-d'under•,dome %Wdbncated' 'It e,"latest'A S M:Er Code,,;Section Vlll; Phrlsion I ` -P'%O stered with the!National^Bbard:. �•� �, *721iquidt evel outddd valvvd oAce re8ucesrefuelin`g,emissions '? 1(acuum pre 'pyrgbgRo sa_veRLML (,( `pney•andrprod'ugt -Applicable federal state,Yr./o`calyegulaiTons� oayrcontam specific requirements for prote'chve coatrngsFandreathodtc p oteq ion: The'purchaser•andlinsrequi ements fdr Wrorecnon s requiredandreoafingmu`s7bejco`ntlnuous andunrntefup,'tedzand'mu-st' 1 complywrthan local sfate_Lr_gahona/to' es •- _F_ ..... _ ia'.. G r-� : ' , Containing •' _General Specifications Conforms to the latest edition of the ASME code for Pressure Vessels, Section Vill, Division 1. Complies with NFPA 58. Rated at 250 prig from -200 F. to 125" F. All tanks may be evacuated to a'full (14.7 psi) vacuum. Vessel Finish: Coated with epoxy red powder. ( Tanks coated with the epoxy powder must be buried). For Aboveground use, tanks may be coated with TGIC powder. Applicable federal, state or local regulations may contain specific requirements for protective coatings and cathodic protection. Theipurchaser and installer are responsible for compliance with all federal, state or local regulations. FLOAT GAUGE SERVICE \` MULTIVALVE RELIEF VALVE -�, WITHDRAWAL DTICE VALVE \. Lp• ANODE -CONNECTION �® FILLER O �0 VALVE U 7 i / NAME /. PLATE FITTINGS LAYOUT UNDER DOME A G U G VESSEL DIMENSIONAL INFORMATION All vessels dimensions are approximate WATER OUTSIDE HEAD OVERALL OVERALL LEG LEG WEIGHT QUANTITY CAPACITY DIAMETER TYPE LENGTH HEIGHT WIDTH SPACING FULL PER 120 wg. 454.2 L 24" Eliip 5' - 5 13/16" T - 0" 10 1/8" T - 0" 245 lbs. L 96D S 12C 609.6 mm 1671.3mm 911.4 mm 257.2 mm 914.4 mm 111.1 kg. 250 wg. 31.5" Hemi T - 2 1/2" T - 7 1/2" 12 3/4" T - 6" 472 lbs. 63 9 946.3 L 800.1 mm 2197.1 mm 1104.9 mm 323.9 mm 1066.8 mm 214.1 k 320 wg. 31.5" Hemi 8' -11 3/4" T - 7 1 /2" 12 3/4" 4' - 0 114" 588 lbs9. 45 9 1211.2 L 800.1 mm 2736.9 mm 1104.9 mm 323.9 mm 1225.6 mm . 266.7 kg. 500 wg. 1892.5 L 37.42" 950.5 mm Hemi 9' -10" 4' -1 7/16" 15" 5' - 0" 871 lbs. 30 6 2997.2 mm 1255.7 mm 381.0 mm 1524.0 mm 395.1 kg 1000 wg. 40.96" Hemi 15' -10 13/16" 4' - 4 5/16" 16 1/4"172911 lbs. 15 5 3785.0 L 1040.4 mm 4846.E mm 1344.6 mm 412.8 mm 27432 mm 784.3 ka Rev: Jan. 27, 2016 Why Tanks Corrode Underground steel tanks corrode due to an electrochemical reaction between the tank and the surrounding soil. The process of corrosion occurs due to small voltage differences on the steel surface that result in the flow of DC current from one location to another. Where current flows from the tank into the soil corrosion occurs. This location is called the anode in a corrosion circuit. Where currentflows from the soil to the tank, no corrosion occurs. The progress of corrosion is determined by the amount of current flowing between the anode and the cathode and whether the locations of the anode/ cathode remain constant overtime. Corrosion rates are generally higher in wet soil environments since the conductivity of the soil promotes the flow of DC current in the corrosion circuit. Corrosion generally exhibits itself on underground tanks in either a general overall rusting or more commonly, a pitting attack. Pit locations may result from metallurgical conditions of the steel suraface or soil variations such as rocks, salts, fertilizer, moisture concentration, oxygen concentration, etc. Preventing Corrosion y. Protecting underground S .:�i tanks from corrosion is easilyachieved bythe use of two commonly applied ws °s protection methods: Z external coating and cathodic protection. These two methods are complementary and should be used in conjunction with the other. An effective external rotective coating insulates the steel from the soil environment, thus preventing the flow of corrosion currentfrom the anode to the cathode. An effective external coating can protect over 99% of the tank surface area. However, no coating is perfect. Damage from construction or soil stresses create tiny defects, which may result in accelerated corrosion at the defect. Cathodic protection prevents corrosion at those defects by applying DC current from an external source, forcing the tank to become cathode. Application of sufficient DC current to the tank will prevent any corrosion from occurring. The two general types of cathodic protection systems are sacrificial and impressed current. Sacrificial systems are used when the amount of current required for the protection is small, such as in underground propane tanks. Impressed current systems are more commonly used for large structures such as large diameter Pipelines. Electrical isolation of the tank from metallic piping systems and electrical grounds is critical for the cathodic protection system's effectiveness. How Sacrificial Cathodic Protection Works Sacrificial systems work by creating a galvanic connection between two different metals. The most common anode material is magnesium, which when coupled to steel results in DC current flow from the magnesium to the steel. The open circuit potential of steel is about -0.50 volts referenced to a copper sulfate electrode. The open circuit potential of magnesium is about -1.55V to-1.80V. By connecting the two metals together, the difference of 1 to 1.25V volts results in current flow to the tank that overcomes the natural corrosion cells that exist on the tank. With this current available to the tank, no corrosion occurs. Magnesium Anodes There are a variety of anode sizes and alloys used for cathodic protection. The two primary alloys are designed as H-1 (or AZ63) and High Potential. The H-1 alloy is produced from recycled magnesium and has an open circuit potential of approximately—1.55V. This alloy is well suited for protection of underground propane tanks. The High Potential alloy is 99% pure magnesium having an open circuit potential up to -1.8V. This alloy should be used for soil applications over 10,000 ohm -cm resistivity. The two most common anode sizes used for underground propane tanks are 9 Ib. and 171b. The size designation relates to the metal weight. 10' of 112 TW insulated wire is attached to the anodes. Anodes are then backfilled in a mixture of gypsum, bentonite, and sodium sulfate to lower the electrical resistance of the anode to soil. The mixture is a low cost, nonhazardous, electrically conductive backfill. The anode and backfill is then packaged in a cotton bag and either a cardboard box or paper bag. Actual shipping weight of these anodes with,,backfill is 27 lb. and 45 lb. Application Recommendations Magnesium anodes can protect underground tanks in most soil conditions. The H-1 alloy is generally very effective. The following chart provides size and quantity recommendations for various size tanks based on conservative design assumptions. This chart covers soil conditions UP to 10,000 ohm -centimeter resistivity. Resistivities higher than 10,000 ohm -centimeter generally represent very dry soils.. Verification of soil resistivity can be performed through soil analysis. Contact us for design recommendations in locations where soil resistivities exceed 10,000 ohm -cm, or if there is no effective external coating on the tank. The propane service line from the tank to the house also must be considered in the cathodic protection design, unless the service line is plastic. All underground steel pipe should be externally coated with a corrosion resistant material. The service line should be electrically isolated at the house with an insulating fitting or union. If service pipe is less than 50' in length, the tank anodes will provide sufficient current to protect both tank and pipe. For longer lengths of,'pipe, an additional anode may be required at the house connections. If another metallic material such as copper is used ,for service piping, the pipe should be electrically isolated from the tank at the fill pipe connection. Copper and steel create a galvanic couplehatwillaccelerate corrosion of the steel tank when directly connected to copper piping. Generally, copper piping does not require cathodic protection. Mechanical Connection Under Dome Cathodic Protection Testing Procedure Equipment Needed: Digital Voltmeter, Red Test Lead Min. 12' Long & Black Lead Min. 2' Long, Reference Electrode (Copper/Copper Sulphate Half -Cell) STEP 1: Using a digital voltmeter insert the red test lead Into the Volt jack of the meter and select the 2 or 20 volt DC scale. Clip red test lead connector to an uncoated metallic area of the tank, preferably to the fill pipe multivalve. A good solid connection Is very important. (DO NOT connect to shroud). STEP 2: Insertthe blacktest lead into the Common jack on the meter, and connect the opposite end of the lead to a charged reference electrode (ys cell). STEP 3: Remove protective cap from the porous plug at bottom end of electrode. Place porous plug end into native soil (remove grass if necessary) at four locations around the tank (one on each side of the tank, and one at each end of the tank). If difficulty is encountered obtaining readings, moisten soil with water or dig 31 cell deeper into the soil. STEP 4: Record all four meter readings on an appropriate form. The least of all four readings should be a minimum' of-0.850v or more negative. (Note: If any of the four readings are below (less negative) -0.850v then the tank is not fully protectedl. Charging Reference Electrode STEP 1: Unscrew and remove porous plug end of new reference electrode. Add deionized or distilled water to the copper sulfate crystals, filling electrode completely. The solution will turn blue in color and there should always be excess crystals at the bottom of the tube. DO NOT USE TAP WATER. STEP 2: Replace porous plug end of electrode and place in an upright position so that the porous plug and is facing in the down position and let stand for 1 hour before use. This will allow the porous plug to become completely saturated before use. Caution: Do not allow electrode to contact oil, road salts, or other substances that may contaminate the solution by absorption through porous plug. Do not allow electrode to %reeze. Soil Type renue sons;;elay, I aand, Gravel, Rocky $andyLoam _ Areas Tank Cap '59o°SOggrohm cm _.y 5000 to 10000 ohm -cm (gal.) SiieT' Oty Alloy' Size Qty. Alloy 120 H-1 150 9#. r ii a=.1' 9# 1 H-1 250 r 9B=_+', 1; H1 9# 2 H-1 325H=U_ ` 9# 2 H-1 500 l 17'_ i _ U' ' 'H-1 t 9# 2 H-1 1000 r ir7# yi =2� 1 ' 9# 4 H-1 1500 cam]7 •;i_2! _ 'H11-j 9# 4 H-1 2000 17- ; {_ 3� { H=7- . 9# 6 H. 'Based on go% effective external coating, 2 ma/ft2 current density, and 30- yearAnode life. Anode Installation 1. Determine size and quantity of anodes from application chart. 2. When a single anode is installed, it should be located near the tank center on either side of tank. 3. When multiple anodes are installed, space them evenly around the tank. See examples below. 1 anode 2 anodes 4 anodes 0 O �i 4.Anodes are shipped in either cardboard boxes or multi -wall paper sacks. Remove outer container and bury the cloth bagged anode. If anode is supplied in plastic bag, remove plastic bag before installing. 5. Install anodes approximately two to three feet from the tank and at least as deep as the center line of the tank. Anodes work best in locations with permanent moisture, so generally the deeper the better. 6.After placing the anode, stretch out the anode connection wire and extend over to a connection point on the tank fill pipe. 7. Cover the anode with approximately six inches of backfill and pour 5 gallons of water on the anode to saturate the prepared backfill. Water is necessary to activate the anode. 8. Connect the anode wire to the tank with a low electrical resistance connection. Examples are threaded stud on the tank fill pipe or any accessible metallic connection point to the tank. All connections should be coated with a moisture -proof material. 9.Ideally, the tank connection is made in the area of the tank fill pipe within the covered dome. With access to the anode wire, subsequent testing of the tank can include measurement of anode output and verification of performance. 10.Verify performance of the anode using an appropriate test procedure. LV3403TR Ideal for use as a first stage regulator on any domestic size ASME or �( DOT container In propane gas installations requiring up to 1,50o,000 BTU's per hour. The regulator Is factory at to reduce container LISTED Pressure to an Intermediate pressure of approximately 10 PSIG. rbzhsr s • Compact design can be connected to a service valve using either a POL adapter or a RegO product pigtail, • Large threaded''/a• RNPT bonnet vent can easily be piped -away underground Installations without the need of glue kits or extra adapters. • Non Adjustable • Large flow orifice resists freeze ups due to water concentration In LPG vapor. • Design provides for good flow regulation at both high and low container pressures. • Built in relief valve and travel stop comply with NFPA 58 over Pressure requirements. • Incorporates W RNPT downstream pressure tap for an easy inline check of the regulator's delivery pressure. • Molded diaphragm provides an o-ring type seal between the body and bonnet. • Body and bonnet are assembled in the USA using the unique, patented RegUlok seal system. Fully painted In brilliant red for complete corrosion protection. Mounting bracket available as an accessory: part number 2302-31 WS2OTL_ZS Body............................................................................................Zinc Bonnet.........................................................................................Zinc Spring........................................................................................ Steel Seat Disc ................................ .................................Resilient Rubber Diaphragm...........................Integrated Fabric and Synthetic Rubber - -- -- _ -• --••• •• p ro=,e,�, anwn9 ena oenvary pressum 20%lower than the regulatorset0ng and derwery pressure 20%kwerthan the set0ng. A14 M&M-Wa. 1D0 Rego Dr. Eton, No 27244 USA v .regopmdocts,com ♦1 (336) 449-7707 Fcaualm Designed to reduce first stage pressure of 5 to 20 PSIG down to bumer pressure, normally 11" w.c. Ideal for medium commercial Installations, vapor meter Installations and normal domestic loads. Thal 9 —s • 90 degree right angle inlet to outer connection for meter or standard installations. • Large vent helps to prevent blockage and has 3/." F. NPT for vent piping. • With 15 PSIG Inlet pressure, regulator is designed to not pass MOM than 2 PSIG with the seat disc removed. • Replaceable valve orifice and valve seat. • Straight line valve closure reduces wear on seat disc • Unique bonnet vent profile minimizes vent freeze over when properly Installed. • Large molded diaphragm is extra sensitive to pressure changes. • Built in pressure tap has plugged %" F. NPT outlet. Plug can be removed with a 3116" hex allen wrench. • Select Brown Finish Can mount directly to vapor meter. It is also suitable for mounting directly to the house piping. It will retrofit Into existing Installations that are currently using a 90 degree, right angle regulator. Body................................... Bonnet Die Cast Zinc ......................................................................... NozzleOriflce ....................................... Dle Cast Zinc ............................................... Spring..................................................................... ...................... Brass Valve Seat Disc.....................................................Resilient ... Steel Rubber Diaphragm ......................... Integrated Fabric and Synthetic Rubber LV4463866RAB•+ 3�• F. NPT I 3/." F. NPT I 3N6" Maximum flow Is based an 10 PSIG (Net and 9' w.c. deliverypressure. •• Mounang Bracket Inoloded. w/Momltiug8tacket 1 F 1 11 1 11 1 111 11 111 1 111 111 111 M 1 111 1 11' at 10 PSIGIG Inlet I g" to 13" W.C. I Over Inlet 00 Rego Dr. Elan, NC 27244 USA w.vw.mgopmdugs.com +l (336) 9637707 ���illsY. A21 11' at 10 PSIGIG Inlet I g" to 13" W.C. I Over Inlet 00 Rego Dr. Elan, NC 27244 USA w.vw.mgopmdugs.com +l (336) 9637707 ���illsY. A21 ES-D-GAC—Generac_InstallSmart Job Name Job Location Engineer Approval Generac® La�KT Flexible Fuel Lines The flexible connection between the gas supply and the gas inlet of a Generac® Stationary Outdoor Backup/Standby Generator Features • Operating Temperature -40°F to 150°F (-40°C to 65.60C) • Operating Pressure MAX 0.5psi (3.45 kPa) • Hydrostatic Burst Pressure MIN 250psl (1725 kPa) • Flexible Tube Material Annealed 304 Stainless Steel • Flare Nut Material Carbon Steel with Zinc Trivalent Chromate Plating • Flare Adapter Material Carbon Steel with Zinc Trivalent Chromate Plating • PVC Dip Coating Gray Heavy Duty, Antimicrobial, UV Stabilizer CSA Group Certificate of Compliance to Product Standards ANSI Z21.75/CSA 6.27 — Connectors for Outdoor Gas Appliances and Manufactured Homes Scope states "...Intended for exterior use above ground for making non -rigid connections... between the gas supply and the gas Inlet of an appliance for outdoor installation that is not frequently moved after installation." In addition section 1.5.4 states the connector is designed for occasional movement after installation. Repeated bending, flexing or extreme vibration must be avoided. Normal operation of a clothes dryer, rooftop HVAC unit or SIMILAR OUTDOOR APPLIANCE DOES NOT constitute extreme vibration or movement. ANSI Z21.24/CSA 6.10 — Connectors for Gas Appliances s�, (Excluding 60/61 Series) c us Product Configurations Contractor Approval Contractor's P.O. No. Representative SKU For use with Generac stationary outdoor backup/ standby generators. Applicable Codes ANSI Z223.1/NFPA 54 National Fuel Gas Code Section 9.6 International Fuel Gas Code QFGC) Section 411.1 B149.1 — Natural Gas and Propane Installation Code (CSA Group) Section 6.21 Uniform Mechanical Code (UMC) Section 1313.6 Uniform Plumbing Code (UPC) Section 1212.0 . Additional Approvals Commonwealth of Massachusetts Board of State Examiners of Plumbers and Gas Fitters Additional Testing UL2200-2015: Stationary Engine Generator Assemblies Section 666 Vibration Test. eommntproductspeciffCsU) sIn US.=Mary units and metric are approdmate and are provided for reference only Far prise Di1( )rt�mont® meWemeNs,p@ase contact eonnontleddead Service. 0ormont raervesthe right to change or morlfy pmduct dedgry""'traction, �$' specGkatlort, ormatedab without prior nad a and vAttW IncurrN anY Wigation to intake such changes and modifianison somroM Pmdoots previgl or subsequanty sold. Refer to the owner's manual for warranty informatbn A WATTS Brand Minimum Flow Capacity at Specified Pressure Drop Straight Length STU/hr. NATURAL GAS, 0.64 SG, 1000 BTU/cu.ft. GeNmb Part Dormonr Part Number t Numb Sfi�ES Namtnal ID Nominal Lenghl In In 05014 0.751n 1.0D in 1.25 in 1.50 in 1000D009193 00979 10000009776 CAN41-4141-24GEN C0414141.48GEN 41 % 24 290,900 356,218 411.395 459.953 503,854 1.751n 2.00 N 544,224 581800 10000009777 CAN41-4141-12GEN 41 41 94 48 217.000 3 265,770 06,884 343,107 375,855 405,970 434,000 10D00000498 CAN51-5151-24GEN 51 72 173,900 1 212,983 1254.932 247,960 301,204 325,337 347,800 10000000499 CM51.5151.48GEN 51 24 581,800 1 48 712,557 822,789 919,907 1,007,707 1,088,448 1,163,600 10000000500 UM51-5151-72GEN 51 442,700 1 72 542,195 699072 699,970 766,779 828,216 885,400 347,800 425,966 491,863 549,920 602,407 650,674 695,600 Straight Length BTU/hr. LP GAS, 1.55 SG, 2500 BTU/cu.ft. GeneniC Do Orr PM Number Part Number SEPIES Nominal ID In Nominal Lenght in 0.501n 0.751n t.001n 1251n 10000009793 CAN41.4141-24GEN 41 %4 24 465,400 569,996 658,175 735,862 1.50N 806096 1.75N 2.00N 10000009776 CAN41.4141-48GEN 10000009M CM41.4141-72GEN 41 Y4 48 344,000 421,312 486,489 543.912 595,825 870,684 643.565 930,80n 688,000 1000D00D498 CAN51.5151-24GEN 41 51 1 72 24 278,240 --- --0 340.773 393,491 439,936 481,926 520,539 556,480 10000000499 CAN51-5151.486EN 51 1 48 1,140,091 1,316,463 1,471,851 1,612,331 1,741,517 1,861,760 10000DO0500 rdN51.5151-72GE1 51 1 708,320 867,511 1,001,716 1,119,952 1,226,846 1,325,145 1,416,640 72 556,480 fi81,546 786,982 879,872 963,852 1,041,079 1,112,960 Generac part number 10000000498 (Dormont part number CAN51-5151.24GEN) can supply a minlmUm of 581,800 BTU/hr.of natural gas ® 0.50 In. water column Pressure drop to the generator. �/iRT1111,70 All Installations must completely comply with all DOrmOnt® manufacturing company warnings and Instructions, national, state and local codes and all appilcable ANSI standards. A WATTS Brand ES-D-GAC_Generac_InstallSmart 1703 USA: T: (800) 387-6668 • F. (724) 733-4808 • Dormom.com Canada: T: (905) 332-4090 • F (905) 332-7068 -' Dormont.ca Latin America: T; (52) 81-1001-8600 • F: (52) 81-800D-7091 • Donnont.com 0 2016 Domnont Maximum Capacity of PE Pipe In Thousands of BTU Per. Hour of L wilh a Gas Pressure or 11.0 In. WC and a Pressure Drop 147 732 ru oc 63 58 172 99 89 81 76 54 70 61 66 48 63 46 44 42. 40 209 $76 188 338 160 140 126 116 107 287 100 94 89 60 85 57 81 64i 78 52 75 569 516 .252 227 208 192 441 391 354 326 303 180 285 169 269 160 162 146 140'. 134 1061 956, 810 712 642 587 5" 508 478 255 453 244 431 233 224: ' 216 411 894 379' 'Maximum Capacity of PE Pipe In Thousands of BTU per Hour of Liquefied Petroleum Gas 576BTUfi=TCF14 with a Gas Pressure of 2.0 psi and a Pressure Drop of 1.0 psi 11300 7586 6008 4j "'� 0-6z3 471 431 399 - 373 351351 309 1,278, 6092 4479 4033 3418 3007 2707 2478 2295 2144 2018 1775 : 1599 14652 9835 7790 6602 5807 5229 4432 3898 3610 3213 2975 2790 2617 2302 2073 $7814 14074 19946 690 8276 7467 6315 5555 5DD2 4578 4239 3962 3729 3280 2953' 43429 29848 19946 16905 14869 13389 71348 9982 8988 8226 7618 7779 6700 5894 5307' 43429 77131 23969 20575 18782 16474 74100 12496 11322 70417 9691 9092 8589 7612 f 6897 706963 71737 56339 47750 42OD0 37B20 32054 28194 25388 23234 21517 20708 18926 76647 14991) e � o as o as .ea as .ay... 236 207 Al °' vv aao vv an ' ,ae IB7 710 139 125 115 706 99 93 88 1/ as 7365 1192 1073 910 800 720 659 611 671 637 508 484 462 443 74 1767 1645 1391 1179 1037 934 855 792 740 696 669 627 599 574 : 651 2508 2202 1983 1680 1478 1331 1218 1128 7054 992 939 893 869 818 786 5903 5232 3563 3019 2656 2391 2789 2D27 1894 17&3 1688 1605 1535 1469• `1412 6903 6232 4740 4057 3596 3258 2997 2788 2616 2477 2347 2239 21744 2060 t1985 72705 11176 10063 8629 7592 6755 6182 6725 5350 5036 4767 4535 4331 4750 '3988 Maximum Capacity of PE Pipe In Thousands of BTU per Hour of Liqquefied Petroleum Gas616BNh=1CFH with a Gas Pressure of 10.0 psi and a Pressure Drop of 1.0 psi (based on a 1.62 specl8c gravity gas) a v a° 2476 1662 a •"- "WORM �va 1® 1114 64 884 749 659 593 643 503 470 442 389 350 T4294 9555 7668 6414 5642 5080 4306 3787 3470 3721 2890 2707 2542 2236 2010 78455 72388 9812 8316 7315 6587 5583 4970 4422 4047 3747 W02 3296 2896 2611 26296 17652 13981 11849 10423 9385 7954 6997 6300 5766 5340 499D 4697 4137 3720 47252 31720 25123 21293 78729 16B65 14294 12672 11321 10361 9595 8967 8440 7423 6620 6396D 37087 29782 25489 22591 20469 77619 '15527 14068 12948 ,12041 11297 10671 9468 8569 793476 89601 70967 60148 52905 47640 40976 35614 31980 29267 27104 25329 23840 20970 18882• > 1, 1707 1607 2213 1946 3753 2773 5665 4983 7334 660D 16004 14077 Ph: 1,800,662.0208 o Fax: 675.325.9407 - Web: www.gclstite.com PLANNING & DEVELOPMENT BOARD OF SERVICES DEPARTMENT COUNTY COMMISSIONERS F L . Building and Code Regulation Division GAS PIPING SCHEMATIC RECEIVED MAR 0 5 2020 IA2] [A4] [SAINwucle County, Permitting [L4] [1_8] [L12] t Ll L3 L5 L7 L9 L11 L2] [1.6] [1.10] [Al] [A3] [A5] TANK SIZE:.Do GALS. APPLICANCE — TYPE/SIZE Al JsWCb& BTU A2 BTU A3 BTU A4 BTU A5 BTU A6 BTU PIPING LENGTH & SIZE L1 3 FT. 3/C INCH DIA. L2�—FT. IINCH DIA. L3 FT. INCH DIA. L4 FT. INCH DIA. L5 FT. INCH DIA. L6 FT. INCH DIA. L7 FT. INCH DIA. L8 FT. L9 FT. L10 FT. L11 FT. L12 FT. Revised 7122114 INCH DIA. INCH DIA. INCH DIA. INCH DIA. INCH DIA. (PIPE NZE WAS TAKEN FROM THE 201 FBC FUEL GAS CODE — TABLE 402 ) 9017 F-0e 16 45(�� p M4,1 c'uces 7,,b12 Website: w ,stlucieco.cov 2300 Virginia Avenue - Fort Pierce, FL. 34982-5652 Phone (772) 462-1553 FAX (772) 462-1578