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  • NIOSH
    Heavy Equipment Near Overhead Power Lines? New Safety Research May Save Your Life

    By Gerald T. Homce, Michael R. Yenchek, H. Kenneth Sacks, James C. Cawley

    Accidents occur when least expected, from sources that we rarely anticipate and with outcomes that can vary greatly. Anyone who has ever been involved in an automobile accident knows, the transition f

  • CIM
    Heavy media cyclone circuits

    By J. Hoover

    "IntroductionThis chapter will discuss the operational and maintenance aspects of a heavy media cyclone circuits as applied to coal processing and using magnetite as the media. It deals with heavy med

    Jan 1, 1989

  • SME
    Heavy Media Selection Functions - Circuit Analysis

    By T. P. Meloy

    Current coal cleaning technology uses heavy media (HM) for the recovery of coal in particles larger than 1/16 of an inch. Through the use of float sink measurements of the feed and products to commerc

    Jan 1, 1982

  • SME
    Heavy Media Separation (4d7619bc-461a-4d27-a4cd-6bd70fccd2df)

    By Vas P. Srinivasa

    This paper examines the role of the heavy media separator in the mineral industry. Procedures used in selecting the separating vessel, developing the process flowsheet, and designing a heavy media cir

    Jan 1, 1981

  • CIM
    Heavy media separation circuits

    By Mark Freberg

    "IntroductionThis chapter is intended to provide information on the operation and maintenance of several pieces of equipment used in heavy media separation. Most heavy media separation circuits, parti

    Jan 1, 1989

  • SME
    Heavy Media Separation Of Aluminum From Municipal Solid Waste

    By E. L. Michaels

    Laboratory and pilot scale tests have been made to deter- mine the utility of heavy media separation, particularly a cone type separator, as a means of recovering aluminum from shredded municipal soli

    Jan 1, 1974

  • SME
    Heavy Media Separations

    By Frank F. Aplan

    Introduction Heavy media separation (HMS), also called dense media or float¬sink separation, is one of the newer forms of gravity concentration. Though the concept can be traced to the last century

    Jan 1, 1985

  • SME
    Heavy Medium Cleaning of – 28 Mesh Coal

    By Edward Skolnik

    The concept of using fluid dense media to separate heavy ore constituents from the lighter gangue dates back to 1858, when it was patented by Sir Henry Bessemer. Its use in coal did not begin until af

    Jan 8, 1980

  • AUSIMM
    Heavy Medium Separation at Iscor's Sishen Iron-Ore-Mine

    The Sishen iron-ore-mine produces 3 pro= ducts with size gradings of 25 to 8 mm, 11 to 5 mm and 5 to 0,2 mm and has a product capacity of 20 Mtpa. Ore is produced at an average Fe content of 66,2

    Jan 1, 1987

  • SME
    Heavy Metal Removal For Water Reuse And Effluent Treatment ? Introduction

    By J. L. Boyd

    The mining and processing of basic metals relies on water as a medium for transport. Metallurgical ores are ground, concentrated, leached and refined in an aqueous medium. Water is used for temperatur

    Jan 1, 1975

  • SME
    Heavy Metal Sorption With Clinoptilolite Zeolite: Soil And Water Treatment Alternatives

    By D. Leppert

    Clinoptilolite zeolite may offer attractive, cost-effective alternatives for remedial cleanup of old minesites, smelters and other sites with heavy metal contamination. Previous research demonstrates

    Jan 1, 1989

  • TMS
    Heavy Metal Stabilization Optimization Study

    By Keith E. Forrester

    This paper presents results of laboratory and field optimization of a proprietary processes developed by FESI for the stabilization of heavy metal bearing wastes. The specific waste studies presented

    Jan 1, 1994

  • IMPC
    Heavy Metals Migration Decrease in the Area of Industrial Facility for Environmental Safety

    By K. V. Fedotov, G. I. Sarapulova

    The study is devoted to the earth's surface protection and is aimed at improving the ecological safety of the territories in the mining industry. Identification of the diagnostic signs and quantitativ

    Jan 1, 2018

  • TMS
    Heavy Metals Removal From Small-Arms Firing Ranges

    By Jerold L. Johnson

    Remediation of small-arms firing ranges is being investigated by the Naval Civil Engineering Laboratory and the U.S. Bureau of Mines. Scheduled closures of military installations, as well as the manag

    Jan 1, 1993

  • TMS
    Heavy Metals Removal from Small-Arms Firing Ranges (d57464b2-215f-4c60-8f75-d50df113d8b3)

    By J. L. Johnson

    Remediation of small-arms firing ranges is being investigated by the Naval Civil Engineering Laboratory and the U.S. Bureau of Mines. Scheduled closures of military installations, as well as the manag

    Jan 1, 1991

  • CIM
    Heavy mineral by-products from Athabasca tar sands

    By Lloyd W. Trevoy

    Syncrude Canada Limited is presently studying commercial production of heavy minerals from plant tailings of the openpit A lhabasca tar sands operation. When tar sands are processed and upgraded to sy

    Jan 1, 1984

  • SME
    Heavy Mineral Deposits Of The Fox Hills Formation Located Near Limon, CO

    By F. L. Pirkle

    A heavy mineral deposit about 1.6 km (1 mile) in length, 0.13 km (0.08 mile) in width and averaging about 3 m (10 ft) in thickness is exposed approximately 130 km (80 miles) east of Denver, along Inte

    Jan 1, 2012

  • SME
    Heavy Mineral Placers (4805d0a4-d7ed-4952-bcb7-1b02a0140894)

    By K. J. Stanaway

    Concentrations of minerals between 3.5 and 5 specific gravity such as ilmenite, rutile and zircon in large accumulations of sand constitute "heavy mineral" placers. Two fundamentally different modes o

    Jan 1, 1991

  • AUSIMM
    Heavy Mineral Prospectivity in the Eucla Basin

    By B Hou

    The Eucla Basin in southern Australia is emerging as an important global source of zircon from heavy mineral sands. Understanding the geological evolution of the basin and movement of heavy minerals d

    Oct 5, 2011

  • TMS
    Heavy Mineral Provenance Studies in the Iditarod and Innoko Districts, Western Alaska

    By T. K. Bundtzen

    Placer gold in the Iditarod and Innoko mining camps of western Alaska is derived from a suite of comagmatic, Late Cretaceous to Early Tertiary, alkali-calcic, meta-aluminous. volcanic-plutonic complex

    Jan 1, 1987