Unanticipated multiple seam stresses from pillar systems behaving as pseudo gob-case histories
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- 作者:Michael Gauna ; gauna.michael@dol.gov ; Christopher Mark
- 关键词:Underground mining ; Coal ; Multiple seam ; Gob ; Ground control
- 刊名:International Journal of Mining Science and Technology
- 出版年:2017
- 出版时间:January 2017
- 年:2017
- 卷:27
- 期:1
- 页码:131-137
- 全文大小:3275 K
- 卷排序:27
文摘
Underground coal mining in the U.S. is conducted in numerous regions where previous workings exist above and/or below an actively mined seam. Miners know that overlying or underlying fully extracted coal areas, also known as gob regions, can result in abutment stresses that affect the active mining. If there was no full extraction, and the past mining consists entirely of intact pillars, the stresses on the active seam are usually minimal. However, experience has shown that in some situations there has been sufficient yielding in overlying or underlying pillar systems to cause stress transfer to the adjoining larger pillars or barriers, which in turn, transfer significant stresses onto the workings of the active seam. In other words, the overlying or underlying pillar system behaves as a “pseudo gob.” The presence of a pseudo gob is often unexpected, and the consequences can be severe. This paper presents several case histories, summarized briefly below, that illustrate pseudo gob phenomenon: (1) pillar rib degradation at a West Virginia mine at 335 m depth that contributed to a rib roll fatality, (2) pillar rib deterioration at a Western Kentucky mine at 175 m depth that required pillar size adjustment and installation of supplemental bolting, (3) roof deterioration at an eastern Kentucky mine at 400 m depth that stopped mine advance and required redirecting the section development, (4) coal burst on development at an eastern Kentucky mine at 520 m depth that had no nearby pillar recovery, and (5) coal burst on development at a West Virginia mine at the relatively shallow depth of 335 m that also had no nearby pillar recovery. The paper provides guidance so that when an operation encounters a potential pseudo gob stress interaction the hazard can be mitigated based on an understanding of the mechanism encountered.