DOCSLIB.ORG

06 Octnov ISSUE 1-56.Indd

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
06 Octnov ISSUE 1-56.Indd Nelson Brothers, Inc. 50 Years of Growth and Service to the Coal Mining Industry t’s humbling for both of us,” said Bill Nelson, speaking for himself and brother, Tony, the two principals in Nelson Brothers Inc., “but as we celebrate our 50th Anniversary this year, we realized we’ve managed this company longer than our founders, our Daddy and uncle, Dugan and Olen Nelson.” “IThere’s a sound basis for the evident pride Bill and Tony take in what the founding brothers of the Nelson company started and what the managing brothers have accomplished. From two brothers with a single truck, Nelson Brothers Inc. has grown to more than 550 employees working through eight major facilities in 10 states and today is the country’s largest suppliers of ANFO (ammonium nitrate fuel oil) explosives and ANFO services to the North American coal mining industry. From the base laid and developed by their father and uncle, in the 26 years since “Daddy’s” death the two brothers—Bill as chief executive offi cer and Tony as president—have overseen a company that has grown more than tenfold in size and today supplies much of the ANFO used in American surface mining. “The history of the company can be divided into two 25-year periods,” Bill explained: “The fi rst 25 as development under our father and the second 25 as growth and expansion under By Art Sanda the sons. But even before then…” 12 Coal People Magazine www.coalpeople.com According to Bill, Tony’s senior by 11 years, “Prior to ammonium when I reached school age the family settled down in Parrish, nitrate (AN) explosives, the explosive of choice was nitro Alabama and Daddy worked as a mechanic. dynamite, the manufacture of which was dominated by duPont, Hercules, Atlas, Austin Powder and others. In fact, the duPont “In 1956, small coal mines were trying to use AN instead of chemical giant of today was built on nitro dynamite. All these big dynamite. They would mix AN with diesel fuel, 94:6, making guys had large dynamite plants all around the country. ANFO, ammonium nitrate fuel oil, explosives. Small operators in Alabama who were doing this kept telling Daddy that this was Nelson Brothers, Inc. “In the mid-late 1940s, there was the Texas City disaster, going to change the whole business into something else and a terrible disaster. On April 16, 1947 the French-registered that he should get involved in it somehow. SS Grandcamp was being loaded with 17 million pounds of ammonium nitrate when a fi re started onboard. Standard “At this time,” Bill continued, “ANFO was about 20 percent the procedure onboard ship in case of a fi re was to close all the cost of dynamite, so operators had a real reason to have it hatches to deprive the fi re of oxygen which, in this case, was work. But it had a way to go. Because ANFO was not as dense exactly the wrong thing to do. When nitrate burns, it creates its as dynamite—meaning less of a bang—the boreholes had to own oxygen. By enclosing that fi re, they created a huge bomb, be drilled closer together, meaning the drilling of a lot more and it exploded with substantial loss of life. There were nearly holes for the same oomph. And, because it was not waterproof, 8,500 victims. ANFO could not be used in wet weather or wet holes, the result of ground water or seepage. The Big Guys, the big dynamite “As unfortunate and tragic an incident as it was, having seen companies, said it wouldn’t work, no way, not in the fi eld, and what nitrate could do, people became interested in ammonium stayed away from it. But all across the country, entrepreneurs nitrate explosives. That’s not the only reason for the interest, strived to make it work. obviously, but it was a large reason,” Bill said. “At that time, Daddy wasn’t interested in considering the Moving to a corner of the room with his arms extended, Bill manufacturing end of the business, but he was interested in animated: “Here were the big guys—duPont, Hercules, Atlas, getting involved in the delivery end of it,” Bill said. “Problem Austin Powder—all in one corner manufacturing nitro-based was, Daddy didn’t have the money for the down payment on his dynamite; Big Business, plants all over the country with a fi rst truck, but his brother, Olen, did. And that year, 1956, they couple of thousand people employed at each one of them. formed Nelson Brothers. They were producing all different size explosives being used all over America, even into the early and mid-1950s. It wasn’t until “I was nine years old at the time,” Bill recalled. “Like any kid, I then that real investigation into the use of AN-based explosives always was following my daddy around everywhere he’d let me. began. I always was in his shop sweeping-up, cleaning tools, whatever, and that carried over to the explosives business.” “In surface mining during this pre-ANFO period, sticks of dynamite up to fi ve inches in diameter and weighing up to 30 lbs a stick continued were stacked by the ton into boreholes. Up until mechanization of underground mining in the early 1960s, explosives also were used in underground mining, dynamites specially formulated to reduce fumes in the underground environment. “Dynamite was both dense and water proof, two things that early AN-based explosives were not. The Big Guys would say: ‘You need those two elements if you are going to have a successful blast.’ And they had a point. AN explosives were less dense than the specifi c gravity of water, which would cause it to fl oat in a wet bore hole. Neither were the AN explosives waterproof, effecting their reliability,” Bill said. “Around the time we are talking, Daddy had been a welder on Tony Nelson, Kathy Robb, Bill Nelson Kathy is a Nelson pipeline construction jobs, causing our family to move three or Brothers employee at the Charleston, WV offi ce four times a year as Daddy followed the work. In 1953 or so, Tony (extreme left) and Bill (fourth from left) at the Nelson Brothers’ Gillette, Wyoming 50 Year Anniversary Celebration 12 OCTOBER/NOVEMBER 2006 Buyer’s Guide 13 Nelson continued Initially, that business was with Spencer Chemical Company, strictly delivering the ammonium nitrate in bags to a mine’s storage building or trailer. Miners would take the AN bags to the boreholes, tear off a corner and, using a dipper, measure out so much diesel fuel for each bag from a five gallon can, creating ANFO. ANFO, unconfined, is quite stable and simply will burn when a match is put to it. In order to have it explode, an initiator first was placed in the hole and then the ammonium nitrate and fuel oil were combined on site and poured into the boreholes. As Bill described it, it was a very crude operation in the beginning. (L-R) Larry Gilmore, President of International Society of Explo- “In 1960, Monsanto approached Daddy to haul for them, as well sives Engineers, presenting to Bill and Tony a plaque on behalf as warehousing AN from their large plant in Luling, Louisiana. of ISEE in congratulations of the 50 Year Anniversary. Spencer, which later was purchased by Gulf Oil Chemicals, got Presentation made at the Celebration Reception on Oct. 12. wind of the deal and fired Daddy and Uncle Olen, so they came to an agreement with Monsanto. “The secret to manufacturing good ANFO, they discovered, was in the 6 to 94 mix, or to be precise, 5.7 to 94.3,” Tony interjected. “Monsanto would ship boxcars of bagged AN, Daddy would “At 5.7 percent fuel oil, the ANFO achieves maximum efficiency. warehouse it and then truck it to the mines as needed. The way At 4 percent, you lose 12 percent of the energy and, at 3 percent, they were adding fuel to the AN at the mines was haphazard at it’s only 80 percent efficient. best. They were adding so much fuel to each bag and, if they began running out of fuel toward the end, well they just would “At the job site, all the miners had to do was put a primer adjust the amount they were adding,” Bill said. assembly into the borehole, open the bag and load the hole with the ANFO. This was 10 times quicker and gave the exact “When the mines asked why someone didn’t build a plant and amount and quality of ANFO the customer needed. Everything do the mixing there, Daddy and Uncle Olen did. That was in the company has done since has been central to how more cost 1962 in Parrish. As it turned out, they couldn’t have picked a effectively AN-based explosives can be used,” Tony said. better location, dead center to the Alabama coal business. It just happened that way. “That accuracy, mixing in the bag, was impossible at best,” he continued. “Additionally, AN comes in prill form, like small 14 Coal People Magazine www.coalpeople.com BBs. When those BBs were loaded into watchmaker who couldn’t see the the sacks, the empty space between digital age coming. them—about 40 percent by volume— was what was creating the low density. “Our first 25 years were all based on To solve problems of low density and no ANFO, HD-ANFO and bulk ANFO, water resistance, they took the AN out everything was based around improving of the bags, ran it through an agricultural the manufacture, shipping and use mill and ground the prills into almost a of the product; making it increasingly powder,” Tony said.
Load more

Recommended publications
  • Chemical Accident Prevention & Preparedness
    Lessons Learned Bulletin No. 5 Chemical Accident Prevention & Preparedness Major accidents involving fertilizers The aim of the bulletin is to provide insights on lessons learned from accident reported in the European Major Accident Reporting System (eMARS) and other accident sources for both industry operators and government regulators. In future the CAPP Lessons Learned Bulletin will be produced on a semi-annual basis. Each issue of the Bulletin focuses on a particular theme. Accident 1 Summary Wholesale and retail storage and distribution In preparing this bulletin, 25 major accidents in eMARS involving fertiliz- Sequence of events was to attack the source of the fire with ers were studied together with an ad- portable fire extinguishers, in the absence ditional 25 accidents from other free A fire occurred in a warehouse storing fer- of activated fire hose reels. Arriving on sources, including also accidents in tilizers and chemical products belonging the site, firemen observed that very thick transport. Events were chosen on the to a wholesale distributor of numerous smoke was emitted from the storage basis that ammonium nitrate or NPK products, including sugar, molasses, fer- compartment. It also appeared that a fertilizer (nitrogen-phosphorus-potas- tilizers, and cereals. The storage instal- fire was burning beneath the mass. How- sium) was involved in the accident. lation was subdivided into 8 compart- ever, the intervention of the firefighters ments of which two contained NPK (15% appeared to focus solely on the presence In general, with some exceptions, N, 8% P, 22% K) fertilizers in quantities of ammonium nitrate fertilizer, ignoring, most accidents occurred in ware- of 600 tonnes and 850 tonnes respec- the nature of the other chemical prod- houses or general chemicals manu- tively.
    [Show full text]
  • Air Pollution and Increased Safety Risks to Workers and Nearby Residents
    1 ACKNOWLEDGEMENTS Written by Ari Phillips with analysis from Courtney Bernhardt and Gabriel Clark-Leach of the Environmental Integrity Project. THE ENVIRONMENTAL INTEGRITY PROJECT The Environmental Integrity Project (http://www.environmentalintegrity.org) is a nonpartisan, nonprofit organization established in March of 2002 by former EPA enforcement attorneys to advocate for effective enforcement of environmental laws. EIP has three goals: 1) to provide objective analyses of how the failure to enforce or implement environmental laws increases pollution and affects public health; 2) to hold federal and state agencies, as well as individual corporations, accountable for failing to enforce or comply with environmental laws; and 3) to help local communities obtain the protection of environmental laws. CONTACTS: For questions about this report, please contact: Tom Pelton, Environmental Integrity Project, (202) 888- 2703 or [email protected] PHOTO CREDITS: Cover Image: The ExxonMobil Baytown Olefin’s plant fire sends a toxic brew of chemicals into the sky on July 31, 2019. Thirty-seven people experienced minor injuring from the explosion, which occurred at a part of the facility where plastics are made. Photo by the Associated Press, used with permission. Page 1: Houston industrial district, Shutterstock. Page 4: Petrochemical complex, La Porte, Texas, by Roy Luck/Flickr. Page 8: Assessment units for the Wolfcamp Shale and Bone Spring Formation of the Delaware Basin, USGS. 2 Plastics Pollution on the Rise Executive Summary hat the word ‘plastic’ means pliable or easily shaped is deceiving. Over the last 50 years plastic has developed a stranglehold over us, with no sign of loosening up. It is T hard to imagine life without plastic: The versatile material is found in computers, phones, medical devices, packaging, and thousands of other products.
    [Show full text]
  • Risk and Safety Management of Ammonium Nitrate Fertilizers: Keeping the Memory of Disasters Alive
    32 | Loss Prevention Bulletin 251 October 2016 Incident Risk and safety management of ammonium nitrate fertilizers: keeping the memory of disasters alive Dr. Zsuzsanna Gyenes, EC Joint Research Centre, Italy; Nicolas Dechy, CHAOS association, France This paper is aimed at keeping the memory of disasters alive, with the new process had fractions with higher ammonium assuming that risk awareness and implementation of safety nitrate (AN) content and this inhomogeneous mass was stored measures are facilitated by case histories. There have been together with the ASN that was dried with the old process. several accidents and a few disasters in the ammonium nitrate Due to higher AN content, lower density, lower water content fertilizer industry, and it is worthwhile to review these from (reduction from 4% to 2% with the new technique) and time to time, beyond the regulation and practice changes changed crystalline structure, the accumulated fine fraction which they triggered. was explosive. In addition, the operational issue was that the storage in large quantity lead to caking. The anti-caking BASF plant, Oppau, 1921 procedure at that time was to use dynamite! It was repeated over 20,000 times with no large explosion before that day. On 21 September in 1921, two consecutive explosions Similar risky procedures were at the origin of other accidents occurred in a silo in the BASF plant in Oppau, Germany, in Kriewald in Germany in 1921 (26 July)25 and Tessenderlo in creating a 20m deep, 90x125m large crater. The entire area Belgium in 1942 (29 April)26. was covered by dark green smoke and there were several additional fires and small explosions.
    [Show full text]
  • The Texas City Disaster
    National Hazardous Materials Fusion Center HAZMAT HISTORY The Texas City Disaster The National Hazardous Materials Fusion Center offers Hazmat History as an avenue for responders to learn from the past and apply those lessons learned to future incidents for a more successful outcome. This coincides with the overarching mission of the Fusion Center – to improve hazmat responder safety and enhance the decision‐making process during pre‐planning and mitigation of hazmat incidents. Incident Details: Insert Location and Date Texas City, TX April 16, 1947 Hazardous Material Involved Ammonium Nitrate Fertilizer Type (mode of transportation, fixed facility) Cargo Ship Overview The morning of 16 April 1947 dawned clear and crisp, cooled by a brisk north wind. Just before 8 am, longshoremen removed the hatch covers on Hold 4 of the French Liberty ship Grandcamp as they prepared to load the remainder of a consignment of ammonium nitrate fertilizer. Some 2,086 mt (2,300 t) were already onboard, 798 (880) of which were in the lower part of Hold 4. The remainder of the ship's cargo consisted of large balls of sisal twine, peanuts, drilling equipment, tobacco, cotton, and a few cases of small ammunition. No special safety precautions were in focus at the time. Several longshoremen descended into the hold and waited for the first pallets holding the 45 kg (100 lb) packages to be hoisted from dockside. Soon thereafter, someone smelled smoke, a plume was observed rising between the cargo holds and the ship’s hull, apparently about seven or eight layers of sacks down. Neither a 3.8 L (1 gal) jug of drinking water nor the contents of two fire extinguishers supplied by crew members seemed to do much good.
    [Show full text]
  • Loss Prevention Bulletin Improving Process Safety by Sharing Experience
    Loss Prevention Bulletin Improving process safety by sharing experience Disaster 1916 Issue 251, October 2016 Anniversaries The great explosion of 1916 1986 Fire and explosion of LPG tanks at Feyzin 1966 Seveso – 40 years on 1986 Chernobyl – 1976 30 years on The Sandoz warehouse fi re – 30 years on The Challenger Space Shuttle disaster Risk and safety management of ammonium nitrate fertilizers 1921 1986 LPBcover251.indd 1 30/09/2016 14:25 I C h e m E S a f e t e ISC y r t n C e IChemE safety training October – December 2016 IChemE offers a range of training courses to help you, Fundamentals of Process Safety your staff and your organisation improve safety and 10–14 Oct, Melbourne, Australia www.icheme.org/fpsmel reduce risk. Comprehensive Explosion Science 11–12 Oct, London, UK All IChemE training courses can be run in-company. www.icheme.org/ces Email [email protected] for a quotation. Gas Explosion Hazards on LNG Facilities 13–14 Oct, London, UK Visit www.icheme.org/courses to view all IChemE www.icheme.org/lng training courses. Layer of Protection Analysis (LOPA) 25–26 Oct, Boksburg, South Africa Register for any course at www.icheme.org/booking www.icheme.org/lopasa Fundamentals of Nuclear Safety 31 Oct–4 Nov, Preston, UK www.icheme.org/fns Fundamentals of Process Safety Management 7–11 Nov, Boksburg, South Africa www.icheme.org/fpsm Layer of Protection Analysis (LOPA) 8–9 Nov, Cork, Ireland www.icheme.org/lopa Human Factors in Health and Safety 16–17 Nov, Melbourne, Australia www.icheme.org/humanfactors Layer of Protection Analysis
    [Show full text]
  • Variables Associated with the Classification of Ammonium Nitrate – a Literature Review
    Variables Associated with the Classification of Ammonium Nitrate – A Literature Review FINAL REPORT BY: Sean Gillis Sreenivasan Ranganathan Fire Protection Research Foundation, Quincy, MA March 2017 © 2017 Fire Protection Research Foundation 1 Batterymarch Park, Quincy, MA 02169-7417, USA Email: [email protected] | Web: nfpa.org/foundation —— Page ii —— FOREWORD Ammonium Nitrate (AN) “is a chemical compound produced in both solid and liquid forms that is commonly used in fertilizers”. The burning rate of technical-grade AN prill falls within the Class 2 oxidizer criteria in Annex G of NFPA 400, 2016. The loss history of AN also indicates potential for unstable reactive hazard properties, uncontrolled decomposition and/or detonation under circumstances that are not fully understood. In the most recent revision of NFPA 400, Hazardous Materials Code, the Technical Committee (TC) classified Ammonium Nitrate as a Class 2 Oxidizer. However recent hazardous material incidents involving AN have resulted in differing views regarding the reactivity of the compound and whether or not it should be considered an unstable reactive in NFPA 400. The different behaviors of AN in different fire situations make it difficult to determine the appropriate safe practices for AN storage and handling. There are also discrepancies between the NFPA and International Fire Code (IFC) classifications of Ammonium Nitrate. As a result there is a need for additional data to assist in the proper classification/treatment of AN. An examination of existing data involving the reactivity of AN will assist the NFPA 400 TC in determining the appropriate classification of Ammonium Nitrate, and perhaps point to a need for future Ammonium Nitrate testing.
    [Show full text]
  • The Role of Leadership and Development of Management Systems to Ensure Safety Performance in Energy Sectors
    THE ROLE OF LEADERSHIP AND DEVELOPMENT OF MANAGEMENT SYSTEMS TO ENSURE EFFECTIVE SAFETY PERFORMANCE A Thesis by SEYEDSHAYAN NIKNEZHAD Submitted to the Office of Graduate and Professional Studies of Texas A&M University in partial fulfillment of the requirements for the degree of MASTER OF SCIENCE Chair of Committee, M. Sam Mannan Committee Members, Efstratios N. Pistikopoulos Mahmoud El-Halwagi Michael Wesson Intercollegiate Faculty Chair, Efstratios N. Pistikopoulos August 2017 Major Subject: Energy Copyright 2017 Seyedshayan Niknezhad ABSTRACT Safety is one of the crucial issues that industry has aimed at improving for many decades and continues to progress. Discoveries show that organizations optimize their effort when they provide effective management systems to support front line employees, supervisors, and senior level managers. In this research, the role of leaders regarding safety in the energy industry is studied, and moreover, how to develop safety management systems to ensure an effective safety performance is surveyed. Leadership has the greatest impact on safety improvement. Leaders by different techniques can increase their influence on employees; set the mission and vision for staff; implement rules; provide resources; improve the teamwork; make effective communication from top to bottom, bottom to top and along the organization, educate staff, develop a safety management system, and create safety culture in the organization. By organizational safety culture, I mean the shared common values that drive organizational performance, more commonly defined as “the way we do around here.” While there are regulations regarding safety, every organization requires self-standard beyond the codified rules to have effective safety programs. Regulations should follow new research to develop new management systems to ensure the highest standards for safety.
    [Show full text]
  • Galveston's Balinese Room
    Official State Historical Center of the Texas Rangers law enforcement agency. The Following Article was Originally Published in the Texas Ranger Dispatch Magazine The Texas Ranger Dispatch was published by the Texas Ranger Hall of Fame and Museum from 2000 to 2011. It has been superseded by this online archive of Texas Ranger history. Managing Editors Robert Nieman 2000-2009; (b.1947-d.2009) Byron A. Johnson 2009-2011 Publisher & Website Administrator Byron A. Johnson 2000-2011 Director, Texas Ranger Hall of Fame Technical Editor, Layout, and Design Pam S. Baird Funded in part by grants from the Texas Ranger Association Foundation Copyright 2017, Texas Ranger Hall of Fame and Museum, Waco, TX. All rights reserved. Non-profit personal and educational use only; commercial reprinting, redistribution, reposting or charge-for- access is prohibited. For further information contact: Director, Texas Ranger Hall of Fame and Museum, PO Box 2570, Waco TX 76702-2570. Galveston’s Balinese Room Galveston’s Balinese Room Born: 1942 – Died 2008 The Balinese Room was built on a peer stretching 600 feet into the Gulf of Mexico. Robert Nieman © All photos courtesy of Robert Nieman unless otherwise noted. For fifteen years, Galveston’s Balinese Room was one of the most renowned and visited gambling casinos in the world. Opened in 1942 by the Maceo brothers, it flourished until 1957, when the Texas Rangers shut it down permanently as a gambling establishment. In the times that followed, the building served as a restaurant, night club, and curiosity place for wide-eyed visitors. Mainly, though, it sat closed with its door locked—yes, it had only one door.
    [Show full text]
  • QP Oil Spill Contingency Plan Proposal
    CENTRAL TEXAS COASTAL AREA CONTINGENCY PLAN JULY 2015 CENTRAL TEXAS COASTAL AREA CONTINGENCY PLAN (CTCAC PLAN) I CENTRAL TEXAS COASTAL AREA CONTINGENCY PLAN JULY 2015 Record of Changes Change Number Date of Change Date Entered Author Date of Review Reviewer 01 01July14 01July14 CTCAC 01July14 MSTC John Gebo 02 01July15 01July15 CTCAC 01July15 MSTC John Gebo IV CENTRAL TEXAS COASTAL AREA CONTINGENCY PLAN JULY 2015 Record of Review (Signed Annually at the Executive Steering Group Meeting) 2014 ________ ________ _______ _______ ________ ________ USCG TGLO EPA TCEQ BSEE TXRRC 2015 ________ ________ _______ _______ ________ ________ USCG TGLO EPA TCEQ BSEE TXRRC 2016 ________ ________ _______ _______ ________ ________ USCG TGLO EPA TCEQ BSEE TXRRC 2017 ________ ________ _______ _______ ________ ________ USCG TGLO EPA TCEQ BSEE TXRRC 2018 ________ ________ _______ _______ ________ ________ USCG TGLO EPA TCEQ BSEE TXRRC 2019 ________ ________ _______ _______ ________ ________ USCG TGLO EPA TCEQ BSEE TXRRC V CENTRAL TEXAS COASTAL AREA CONTINGENCY PLAN JULY 2015 TABLE OF CONTENTS 1000 INTRODUCTION ..................................................................................................................................................... 1 1100 INTRODUCTION/AUTHORITY .................................................................................................................. 1 1200 GEOGRAPHIC BOUNDARIES ................................................................................................................... 1 1210 Sector
    [Show full text]
  • Bombs, Explosions and Preparedness
    Bombs, Explosions and Faculty Preparedness: A New Role for Public Ziad N. Kazzi, MD, FAAEM Health and First Assistant Professor Responders Co-Director Center for Emergency Infections & Satellite Conference and Live Webcast Emergency Preparedness Tuesday, March 27, 2007 Department of Emergency Medicine 12:00 - 1:30 p.m. (Central Time) University of Alabama at Birmingham Produced by the Alabama Department of Public Health Video Communications and Distance Learning Division Program Objectives FBI Reported Bombings, 1988-1997 • Describe important historical events involving explosions. • Discuss different clinical aspects of blast injuries. • Describe public health and first responder activities in reaction to explosions and blasts. FBI Bombing Database 1988-1997 FBI Bombing Database 2000 1916 1911 1880 1988-1997 1800 1600 1551 1552 • 17,579 bombings 1457 1400 1212 1200 • Numbers doubled over the 10 year 1000 931 period 800 641 Number of Bombings 593 582 600 538 545 423 427 406 378 • Number of bombing peaked in 1992 400 267 203 200 156 0 • 78% were explosives and 22% were 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 Explosive Bombing Years 1988-1997 incendiaries Incendiary Bombing FBI Bombing Database 1988-97 FBI Bombing Database 1988-1997 14001400 12001200 • 427 deaths with a peak in 1995 10001000 (Oklahoma City bombing) 800800 600 600 • 4,063 bomb-related injuries 400400 200200 Number of FBI Reported Deaths and Injuries Number of FBI Reported Deaths and Injuries • Incendiary bombs caused more 0 19881988 19891989 19901990 1991 1992 1993 1994 1995 1996 1997 injuries than explosives InjuriesInjuries Deaths Years 1998 - 1997 Special Characteristics of Special Characteristics of Bombing Victims Bombing Victims • Bombing resulted in significantly different: • Victims of terrorist bombings (906) –Injury complexity were compared with 55,033 –Increased severity casualties of non-terror related –More body regions involved –Enhanced use of intensive care trauma.
    [Show full text]
  • Profile 2019.Pub
    Aerial View of Texas City-La Marque (looking south toward Galveston Island) Page 2 Texas City—La Marque Chamber of Commerce 2 Texas City — La Marque Chamber of Commerce 9702 Emmett F. Lowry Expressway P. O. Box 1717 Texas City, Texas 77592 Telephone: 409-935-1408 Fax: 409-316-0901 Hours: Monday—Friday 8:30 am to 5:00 pm www.tclmchamber.com Chamber Administration President ............................................................................ Jenny Senter Ofϐice Manager/Administrative Assistant……….Leanne Post Communications Director ...................................... ..Lorrie Koster Member Relations Manager……………….....…..…..Lauren Perez Special Projects Coordinator……………….…...…Jessica Spangle 2020 Executive Board (Meets 10 am 4th Wednesday of each month) Chairman ……..………………………….………Rusty Plackemeier Chairman Elect…………………………………....…Georgia Meyer Vice Chairman/Treasurer…...………………....Jim MacPherson Vice Chairman ……………..……………..…Genevieve McGarvey Vice Chairman…………………………………….………...Ron Assad Vice Chairman…………………………………………..Gail Figueroa Texas City-La Marque Chamber of Commerce Vice Chairman………………………………………….Phillip Orange Jimmy Hayley Building Past Chairman………………………………………..…Sergio Matute 9702 E.F. Lowry Expressway Texas City, Texas 77591 President……………………………………………….......Jenny Senter 409.935.1408 2020 Board of Directors (meets 11:30 a.m. on the 4th Wednesday of each month) Ron Assad…………………………………………….………...……...Gallant Builders April Jones………………………………………….….Queens Attic Boutique Ramiro Barba……………………………………….……………...Port of Texas City Caitlin
    [Show full text]
  • Ammonium Nitrate Disaster Timeline
    AMMONIUM NITRATE DISASTER TIMELINE When heated, ammonium nitrate decomposes non-explosively into gases of oxygen, nitrogen, and water vapor; however, it can be induced to decompose explosively by detonation into nitrous oxide and water vapor.[1] Large stockpiles of the material can be a major fire risk due to their supporting oxidation, and may also detonate, as happened in the Texas City disaster of 1947 which led to major changes in the regulations for storage and handling. There are two major classes of incidents resulting in explosions: • In the first case, the explosion happens by the mechanism of shock to detonation transition. The initiation happens by an explosive charge going off in the mass, by the detonation of a shell thrown into the mass, or by detonation of an explosive mixture in contact with the mass. The examples are Kriewald, Morgan, Oppau, Tessenderlo, and Traskwood. • In the second case, the explosion results from a fire that spreads into the ammonium nitrate (AN) itself (Texas City, Brest, Tianjin, Beirut), or to a mixture of an ammonium nitrate with a combustible material during the fire. The fire must be confined at least to a degree for successful transition from a fire to an explosion (a phenomenon known as "deflagration to detonation transition", or DDT). Pure, compact AN is stable and exceedingly difficult to initiate. However, there are numerous cases when even impure AN did not explode in a fire. Ammonium nitrate decomposes in temperatures above 210 °C (410 °F). Pure AN is stable and will stop decomposing once the heat source is removed, but when catalysts are present, the reaction can become self-sustaining (known as self-sustaining decomposition, or SSD).
    [Show full text]