TEST REPORT for the ARID TECHNOLOGIES VAPOR RECOVERY UNIT installed in LANTANA, FL



Similar documents
Source Sampling Manual Volume II

NOTIFICATION OF PERFORMANCE TESTING FOR GASOLINE DISPENSING FACILITIES (GDFs) NESHAP 40 CFR, Part 63, Subpart CCCCCC (Sections

Control Device Requirements Charts For Oil and Gas Handling and Production Facilities

Method to Determine PERFORMANCE OF INDIRECT-FIRED WATER HEATERS March 2003 Edition

Subpart XX Standards of Performance. Terminals. Environmental Protection Agency

5.2 Transportation And Marketing Of Petroleum Liquids General

STATE OF COLORADO PORTABLE ANALYZER MONITORING PROTOCOL

Texas Commission on Environmental Quality Page 1 Chapter Control of Air Pollution from Nitrogen Compounds

Air Eliminators and Combination Air Eliminators Strainers

Equivalents & Conversion Factors 406 Capacity Formulas for Steam Loads 407 Formulas for Control Valve Sizing

Thermal Dispersion Mass Flow

Clean Diesel versus CNG Buses: Cost, Air Quality, & Climate Impacts

Guidelines for Calculating and Reporting Emissions from Bulk Loading Operations December 2013

Vacuum Control. Vacuum Applications. Vacuum Regulators. Vacuum Breakers (Relief Valves) Vacuum Control Devices. Vacuum Terminology

(a) Method 1 Sample and Velocity Traverses for Stationary Sources.

Process Safety Management of Highly Hazardous & Explosive Chemicals. Application, Exclusions & Definitions

Appendix C: Conversions and Calculations

UNDERSTANDING REFRIGERANT TABLES

KNC Model 3666 Automatic Pressure Calibration System

Thermal Mass Flow Meters

ISO 9001 Certified Manufacturing Facility SPECIFICATIONS

1. Standard conditions are in. Hg (760 mm Hg, psia) and 68 F (20 C).

LNG Fuel Tank System LNG Tank overview

(Adopted July 7, 1989)(Amended December 7, 1990) (Amended May 13, 1994) FUGITIVE EMISSIONS OF VOLATILE ORGANIC COMPOUNDS

MERCURY REMOVAL FROM NATURAL GAS AND LIQUID STREAMS ABSTRACT. Giacomo Corvini, Julie Stiltner and Keith Clark UOP LLC Houston, Texas, USA

Leak free means a system where no gasoline is leaked while the system is

Problems with Hypo: Best Design Practices for Smooth and Efficient Sodium Hypochlorite Feed Systems Chad Hantelman, City of Bremerton Jeff Zahller,

Stack Sampling Stack sampling or source sampling

THE DETECTION OF GREENHOUSE GASES

Custody Transfer Measurement. with the V-Cone Flowmeter

NEW JERSEY SMALL BUSINESS ENVIRONMENTAL ASSISTANCE PROGRAM. New Jersey Fuel Dispensing Facilities Compliance Calendar

Emission Facts. The amount of pollution that a vehicle emits and the rate at which

Air Quality Performance Test Guidelines. Kansas Department of Health and Environment Bureau of Air and Radiation

SIZING AND CAPACITIES OF GAS PIPING

EXPERIMENT 13: THE IDEAL GAS LAW AND THE MOLECULAR WEIGHT OF GASES

Laminar Flow Elements

Chapter 19 Purging Air from Piping and Vessels in Hydrocarbon Service

1805 Series Relief Valves

ACFM vs. SCFM vs. ICFM Series of Technical White Papers from Ohio Medical Corporation

Calibration Certificate

The Versatile Differential Pressure Transmitter. By David Gunn Honeywell Process Solutions

Standards and best practice guidelines for vapour recovery at petrol service stations. Department of Environment, Climate Change and Water NSW

User s Manual Laminar Flow Elements

Conversion Formulas and Tables

Lessons Learned from Natural Gas STAR Partners. Installing Vapor Recovery Units on Storage Tanks. Executive Summary. Technology Background

Inspection, Measuring and Test Equipment (IMTE) Calibration

Ethanol Vehicle and Infrastructure Codes and Standards Citations

Propane Gas Underground Systems: Residential Infrastructure Requirements and Energy Benefits

The paper addresses the boil-off in the cryogenic industry and details the specifics of it when applied to vehicle LNG tanks.

Recommended Fuel Piping Specification For UPP Piping, UL-971

Recharge Procedure for Telemark TVP-2000 and TVP-3500

Lightweight, compact, ergonomic, safe POLARIS FID. Portable TOC Analyser for Stack Emissions

NSPS Subpart OOOO: Applicability and Compliance Basics

In-Line Electronic Flow Switches

SPILL PREVENTION, CONTROL AND COUNTERMEASURE PLAN

Statement of Basis SCA Tissue North America, LLC

Notes. Material 1. Appropriate Flammable Liquids

Subpart I Delaware. 40 CFR Ch. I ( Edition) (10) Amendments to Section V (Surveillance)

Continuous Monitoring Manual

Fiscal Measurement Natural Gas

BP WIND ENERGY POLICIES AND PROCEDURES

Air Quality Regulation of the Oil and Gas Production Sector in Colorado and Beyond. Garry Kaufman Holland & Hart LLP

GTM PORTABLE GAS TRANSPORT. a breakthrough in high pressure gas transports, holding twice as much a comparable steel transports at 40% of the weight

Module 5: Combustion Technology. Lecture 34: Calculation of calorific value of fuels

UNIT (1) MEASUREMENTS IN CHEMISTRY

Section IV VACUUM PUMPS. Vacuum Pumps: Basic Operation

Nitrogen Blanketing for Methanol Storage and Transportation

AN INSTRUMENT FOR GRAVIMETRIC CALIBRATION OF FLOW DEVICES WITH CORROSIVE GASES. J. O. Hylton C. J. Remenyik Oak Ridge National Laboratory *

APPENDIX O. Spill Prevention and Emergency Response Plan. G3 Terminal Vancouver Port Metro Vancouver Project Permit Application APPENDIX O

PENNSYLVANIA DEPARTMENT OF ENVIRONMENTAL PROTECTION

AUTOMATIC CHANGEOVER MANIFOLD Series 915

= 800 kg/m 3 (note that old units cancel out) J 1000 g = 4184 J/kg o C

Technical Requirements for Aboveground Storage Tanks (ASTs) Storing Class IIIB Liquids (other than used oil)

NEW JERSEY SMALL BUSINESS ENVIRONMENTAL ASSISTANCE PROGRAM. Dry Cleaner Compliance Calendar 2012

Effects of Atmospheric Pressure on Gas Measurement


RULE DRY CLEANERS USING SOLVENT OTHER THAN PERCHLOROETHYLENE

One basic concept in math is that if we multiply a number by 1, the result is equal to the original number. For example,

Requirements for Hydrogen Storage and Use

Tips from the Help Desk

Molar Mass of Butane

Northeast Gas Association (NGA) 2012 Sales and Marketing Conference. Mike Manning Director of Marketing and Business Development AVSG LP Boston, MA

MTI10 Insertion and MTL10 In-line Thermal Mass Flowmeter and Temperature Transmitter

Online Infrared Flue Gas Analyzer Gasboard 3000

Fundamentals of Vapor Recovery

In-Line Electronic Flow Switches

Index Page. Pumping Systems Intensifiers Gas Boosters High Pressure Generators

Michigan Dry Cleaning Environmental Compliance Workbook

The following definitions apply with regard to requirements specified in this document:

MATHESON STACK EMISSION CALIBRATION PROGRAM. Experience the MATHESON Commitment to Supply Chain Excellence

Resource and Environmental Profile Analysis of Polyethylene Milk Bottles and Polyethylene-coated Paperboard Milk Cartons

Technical & Sizing Bulletin for Meriam LFEs. Laminar Flow Elements

CONTINUOUS MONITORING MANUAL. DEPARTMENT OF ENVIRONMENTAL QUALITY AIR QUALITY DIVISION 811 SW SIXTH AVENUE Portland, Oregon 97204

THE BASICS Q: What is VOC? Q: What are flashing losses/voc emissions from hydrocarbon storage tanks? - 1 -

The Fundamentals of Gas Flow Calibration

E - THEORY/OPERATION

RGC-IR Remote Gas Calibrator for IR400

Transcription:

Project No. 148 TEST REPORT for the ARID TECHNOLOGIES VAPOR RECOVERY UNIT installed in LANTANA, FL Prepared for: Mr. Ted Tiberi Arid Technologies, Inc. 130 North LaGrange Rd. LaGrange, IL 60525 Prepared By: P.O. Box 8022 19390 610/255-1423 610/255-5745 fax

Table Of Contents Page No. 1.0 INTRODUCTION... 3 2.0 SUMMARY OF RESULTS... 4 3.0 FACILITY and SYSTEM OPERATION... 5 3.1 VAPOR COLLECTION and TRANSFER... 5 3.2 VAPOR RECOVERY UNIT (VRU)... 5 4.0 TEST PROCEDURE... 6 4.1 TEST EQUIPMENT and INSTALLATION... 6 4.2 TEST EQUIPMENT CALIBRATION... 6 4.3 ANALYSIS PROCEDURE... 7 4.4 DATA ANALYSIS... 7 5.0 CALCULATIONS... 8 6.0 TEST RESULTS... 10 APPENDIX A ONE MINUTE RESULTS - VENT WITH PV VALVE OFF APPENDIX B ONE MINUTE RESULTS - PERMEATOR APPENDIX C ONE MINUTE RESULTS - VENT WITH PV VALVE ON APPENDIX D GASOLINE DISPENSING RECORDS APPENDIX E GASOLINE LABORATORY RESULTS APPENDIX F CALIBRATION RECORDS -2-

1.0 INTRODUCTION (MTS) conducted an emission test program at a retail gasoline loading station located in Lantana, FL for the purpose of demonstrating capture efficiency of the Arid Technologies, Inc. vapor control unit and for the purpose of comparing vent stack emissions when PERMEATOR is OFF versus ON. The testing period was continuous and lasted approximately 72 hours in length. Sampling was conducted at the outlet vent to the underground storage tanks when the PERMEATOR was OFF and at three locations from the PERMEATOR vapor recovery unit which is operated to control hydrocarbon (VOC) emissions during gasoline dispensing operations. The emission rates are reported as total hydrocarbons in pounds per 24 hour period, pounds of hydrocarbons emitted from the vapor control unit per 1000 gallons of gasoline loaded into vehicles, and processor total hydrocarbon capture efficiency in percent. Matus Technical Services used EPA test procedures in 40CFR60 Subpart XX, Standard of Performance for Bulk Gasoline Loading Terminals. The specific parameters measured included the following: At The Outlet Test Location: Total hydrocarbons by NDIR (Method 25B), exhaust volume by volume meter (Method 2A), volume meter temperature by thermocouple, outlet meter pressure by pressure transducer At The Inlet Test Location: Total hydrocarbons by NDIR (Method 25B) Dispensing Operations: Gasoline volume dispensed into vehicles. Vapor Connections and Vapor Collection Piping: Leak test by explosimeter (Method 21). Matus Technical Services was responsible for all on-site sampling as well as for the submission of this final report of the test results which include a description of the sampling and analytical methods and the calculations used. -3-

2.0 SUMMARY OF RESULTS The emission rate for the vapor control device and vent stack at this gasoline dispensing facility was determined. The results of the test under each condition are summarized in Table 2-1 below. Table 2-1 TEST RESULTS TERMINAL DESCRIPTION... Retail Gasoline Dispensing TEST DATE/TEST PERIOD... 2/14-15/05 2/15-16/05 2/16-17/05 TEST CONDITIONS... Permeator Off Vent Off Permeator On Permeator Off Vent On GASOLINE LOADED (Gallons)... 19,186 19,121 18,908 AVERAGE INLET CONCENTRATION % (C3)... NA 38.52 NA AVERAGE OUTLET CONCENTRATION % (C3)... 39.79 0.72 41.58 AVERAGE HYDROCARBON EMISSION... (lbs/1000 gallons) 3.48 0.014 1.20 HYDROCARBON EMISSION RATE (lb/24hr)... 66.84 0.27 22.75* HYDROCARBON REMOVAL EFFICIENCY... (calculated using total inlet and outlet masses) NA 99.27 NA MTS PERSONNEL IN ATTENDANCE... Harold N. Matus P.E. *Note: An unquantifiable amount of gasoline vapors were released to atmosphere due to leaky tank fill points and during tank filling operation. -4-

3.0 FACILITY AND SYSTEM OPERATION 3.1 Vapor Collection and Transfer This site performs Stage II vapor recovery at its Lantana, FL retail operation. There are twelve fueling points equipped with Gilbarco Vapor Vac dispensers at this facility. 3.2 Vapor Recovery Unit (VRU) The PERMEATOR gasoline vapor processor is a membrane system which allows gasoline vapors to pass through and back into the storage tank, while preventing air from permeating the membrane which is vented to atmosphere. -5-

4.0 TEST PROCEDURE The vapor recovery unit hydrocarbon emission rate will be determined from processor outlet hydrocarbon concentration and outlet volume. The test methods MTS will use are specified in 40CFR60 Section 60.503 of Subpart XX. The methods include EPA Standard Reference Methods 2A, 21 and 25B. 4.1 Test Equipment and Installation In this system the retentate, or exhaust of the PERMEATOR was hard piped to a roots meter. The inlet analysis equipment consists of a Horiba Model PIR-2000 non-dispersive infrared analyzer (NDIR). The analyzer was operated in the range of 0-60% as propane and was calibrated on-site with propane in nitrogen standards. Inlet samples were drawn from the vapor line upstream of the point where the vapor line enters the recovery unit. A stainless steel sample pump with Teflon diaphragm was used to draw the sample from the inlet through a Teflon sample line to the inlet hydrocarbon analyzer. The permeate or return analysis equipment consisted of a Summit non-dispersive infrared analyzer (NDIR). The analyzer was also operated in the range of 0-60% as propane and was calibrated on-site with propane in nitrogen standards. Permeate samples were drawn from the vapor line upstream of the point where the vapor line returns to the storage tanks. A stainless steel sample pump with Teflon diaphragm was used to draw the sample from the permeate line through a Teflon sample line to the inlet hydrocarbon analyzer. Outlet volume was measured with a Romet model RM1000DCID rotary gas meter. A Pulse-A- Matic transmitter, attached to the rotary gas meter, sent a single pulse for every half a cubic foot through the meter. Using test ports in the hard piping, temperature was measured with a K type thermocouple and meter pressure was measured with a Rosemount pressure transmitter. Outlet samples were drawn from a site on or near the rotary gas meter. The outlet analyzer was a Horiba Model PIR-2000 NDIR analyzer operating in the range 0-4% C 3. A stainless steel sample pump with Teflon diaphragm was used to draw the sample from the outlet through a Teflon sample line to the outlet analyzer. The analysis system was housed in a laboratory trailer parked adjacent to the recovery unit. A Campbell Scientific data acquisition system (DAS) was used to collect and log the data obtained from the above mentioned instrumentation. The DAS monitors readings once each second and reports the results in one minute averages. 4.2 Test Equipment Calibration Analyzer calibration gases will conform to approximately 25, 50 and 90% of full range. Zero reference gas was hydrocarbon free air. All calibration gases conformed to applicable Reference Method requirements, and were traceable to NIST Standard Reference Materials. -6-

After field use, the dry gas meter and rotary meter were checked at an intermediate flow rate of approximately 60% of rated flow. If the calibration values have changed less than 1.5%, the field data are acceptable. If a change from the previous calibration values is more than 1.5%, the meter will be recalibrated over its full range of flow. Temperature and pressure transmitters used for field measurements were calibrated after testing. Calibration data forms for the rotary meter, thermocouple, and pressure transmitters are shown in Appendix C. 4.3 Analysis Procedure Prior to initiating the emissions test, all vapor fittings on the processor were leak tested. The test lasted 72 hours. Two approximate 24 hour periods were without the PERMEATOR operating. One of these 24 hours was with the pressure vacuum (PV) valve removed from the vent pipe and the second 24 hour period was with the PV valve attached to the vent pipe. During these two time frames only the outlet analyzer and flow were monitored. The third 24 hour period was while the PERMEATOR is in operation and the inlet and outlet hydrocarbon concentrations were continuously recorded. The analyzers were zero and span checked about once every six hours. The average volume meter temperatures and pressures, during each one minute interval, were logged by the DAS and used to convert actual meter volume to standard conditions. During the test period gasoline dispensing data will be gathered from the computers logging the gasoline loading data. 4.4 Data Analysis The hydrocarbon analyzer readings were averaged by the DAS over each one minute interval. The vapor volumes were obtained by totaling the number of pulses over each one minute period. The volumes were then converted to standard conditions using the recorded temperature and pressures. Inlet and return volumes were calculated from outlet composition using the formulas described in Method 2B which are included in the next section. The outlet mass was then calculated as the product of outlet volume, pollutant concentration and the standard density of the pollutant. The pounds per 1000 gallons dispensed rating was calculated by dividing the total hydrocarbon mass emitted by the amount of gasoline dispensed. -7-

5.0 CALCULATIONS The outlet hydrocarbon (HC) mass is calculated from the measured outlet volume corrected to standard conditions, the outlet HC concentration as propane and the density of propane. Standard conditions are 68 degrees F and 29.92 inches Hg. The outlet volume during any one minute test interval is corrected to standard conditions using the formula: Vscf (out) = 17.65 (Vacf) ( T ( + P A ) 460) (SCF) Where: 17.65 = Standard Temperature / Standard Pressure V acf = Recorded meter volume in cubic feet P A = Absolute pressure (barometric plus turbine meter) in inches of mercury T = Temperature in volume meter in F The mass of hydrocarbons emitted from the outlet during any one minute test period is calculated from: MCH (out) = 519.5 (Vscf (out) ) (HC (out) ) (mg) Where: HC (out) = Hydrocarbon concentration at the outlet in %C 3 Note: The density of propane is 51,950 mg/ft 3 For recovery efficiency of the PERMEATOR, the feed volume is calculated from the outlet volume, outlet hydrocarbon concentration, permeate hydrocarbon concentration and inlet hydrocarbon concentration. Vscf (in) = ( Vscf ( out) ( HC )( HC ( p) ( P) HC HC ( in) ) ( out) ) Where: HC (in) = Hydrocarbon concentration at the inlet in %C 3 HC (P) = Hydrocarbon concentration at the permeate in %C 3 The inlet mass during any one minute test interval is: MHC (in) = 519.5 (Vscf (in) ) (HC (in) ) -8-

The hydrocarbon removal efficiency is calculated from the inlet and outlet mass. Efficiency can be calculated on an hourly basis using the total mass in and out for the hour or overall for the entire test period using the overall mass in and out. HC (eff) = MHC MHC ( in) MHC ( in) ( out) x 100 (%) The gallonage weighted average emission is calculated from the total amount of hydrocarbons emitted divided by the total amount of gasoline dispensed. M/L (avg) = MHC( out ) (lb/1000 gal) Ld(453,592) Where: Ld = Gasoline loaded in gallons. -9-

6.0 TEST RESULTS The one minute test results are presented in Appendices A, B and C includes: sample gas concentrations, inlet and outlet volume in standard cubic feet (SCF), inlet and outlet hydrocarbon mass in grams and milligrams respectively, and hydrocarbon recovery efficiency. During the test program there were several times when gasoline vapors would be released to atmosphere and could not be quantified. Most of this occurred during tank filling operations. It can be assumed that more vapors were released from the tanks during tank filling operations when the tank had a greater backpressure in the tank. The greatest amount would be released when the tank had 3 inches of backpressure from the PV valve and the PERMEATOR is not in operation. There was also leakage at the tank fill points in the beginning of the third day of testing which was also when the PERMEATOR was not in operation. This leakage prevented the pressure in the tanks to build up to the level necessary to release the PV valve. After the tank fill points were tightened the pressure in the tanks did build up thus causing the PV valve to steadily release gasoline vapors. Included in Appendix D is the gasoline dispensing activity. Samples of the gasoline in the storage tanks were analyzed and the results are located in Appendix E. Instrument calibration records and calibration gas certificates are included in Appendix F. -10-

APPENDIX A ONE MINUTE RESULTS - VENT WITH PV VALVE OFF

APPENDIX B ONE MINUTE RESULTS - PERMEATOR

APPENDIX C ONE MINUTE RESULTS - VENT WITH PV VALVE ON

APPENDIX D GASOLINE DISPENSING RECORDS

APPENDIX E GASOLINE LABORATORY RESULTS

APPENDIX F CALIBRATION RECORDS

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information