On the Application of Explosion-Proof Modification Technology</br> for Construction Machinery and Vehicles for the Gas-Rich Huayingshan</br> Tunnel on the Nanchong-Dazhu-Liangping Expressway

Home | About Journal | Editorial Board | Instruction | Subscription | Advertisement | Message Board | Contact Us | 中文

MODERN TUNNELLING TECHNOLOGY

2013, Vol. 50

Issue (4) :197-202 DOI:

Current Issue | Next Issue | Archive | Adv Search

<< [an error occurred while processing this directive] | [an error occurred while processing this directive] >>

On the Application of Explosion-Proof Modification Technology
for Construction Machinery and Vehicles for the Gas-Rich Huayingshan
Tunnel on the Nanchong-Dazhu-Liangping Expressway

（1 Sichuan Communication Engineering Quality Supervision Bureau, Chengdu 610041;
2 Sichuan Nanchong-Chongqing Expressway Co. Ltd., Nanchong 637000）

Abstract
References
Similar articles

Download: PDF (0KB) HTML (1KB) Export: BibTeX or EndNote (RIS) Supporting Info

Abstract Because of the great potential for safety hazards in gas-rich tunnels, explosion-proof modifications should be carried out for the construction machinery and vehicles used in these cases. Currently, there are no technical standards or regulations concerning explosion-proof modifications in the highway industry, so the relevant standards are referenced from other industries. Using the Huayingshan tunnel of the Nanchong-Dazhu-Liangping expressway as an example, this paper elaborates upon the technical status of explosion-proof modifications of construction machinery and vehicles, and it introduces the modification plan, main refitted systems, and practical application in detail.

	Service

	Email this article
	Add to my bookshelf
	Add to citation manager
	Email Alert
	RSS
	Articles by authors

Keywords： Gas-rich tunnel Construction machinery and vehicles Explosion-proof modification

Abstract： Because of the great potential for safety hazards in gas-rich tunnels, explosion-proof modifications should be carried out for the construction machinery and vehicles used in these cases. Currently, there are no technical standards or regulations concerning explosion-proof modifications in the highway industry, so the relevant standards are referenced from other industries. Using the Huayingshan tunnel of the Nanchong-Dazhu-Liangping expressway as an example, this paper elaborates upon the technical status of explosion-proof modifications of construction machinery and vehicles, and it introduces the modification plan, main refitted systems, and practical application in detail.

Keywords： Gas-rich tunnel, Construction machinery and vehicles, Explosion-proof modification

published: 2013-03-28

Cite this article:

.On the Application of Explosion-Proof Modification Technology
for Construction Machinery and Vehicles for the Gas-Rich Huayingshan
Tunnel on the Nanchong-Dazhu-Liangping Expressway[J] MODERN TUNNELLING TECHNOLOGY, 2013,V50(4): 197-202

URL:

http://www.xdsdjs.com/EN/ 或 http://www.xdsdjs.com/EN/Y2013/V50/I4/197

　

No references of article

[1]	ZI Xiaoyu1 SHEN Yusheng1 ZHU Shuangyan1 LUO Ningning2 YANG Jiaqi1 CAO Bangjun1.Study on the Deformation Failure Laws and Support Measures for Tunnels in Layered Phyllite[J]. MODERN TUNNELLING TECHNOLOGY, 2021,58(3): 196-204
[2]	TANG Bin XU Wenping.Discussion and Suggestions for Explosion-proof Based Modification of Construction Machinery and Vehicles in the Gas Tunnel[J]. MODERN TUNNELLING TECHNOLOGY, 2019,56(5): 67-71
[3]	WANG Bo-1, GUO Xin-Xin-1, HE Chuan-1, WU De-Xing-2.[J]. MODERN TUNNELLING TECHNOLOGY, 2018,55(5): 1-10
[4]	Shu Heng, Wu Shuyuan, Li Jian, Guo Xiaohong.Health Monitoring Design for Extra-Large Diameter Underwater Shield Tunnels[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 32-40
[5]	Tuo Yongfei, Guo Xiaohong.General Design and Key Technologies of the Nanjing Weisan Road River-Crossing Tunnel Project[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 1-6
[6]	Lin Xin1, Shu Heng1, Zhang Yaguo2, Yang Linsong1, Li Jin1, Guo Xiaohong1.Study of the Longitudial Profile Optimization of Large-Diameter Shield Tunnels in Mixed Ground with Very High Water Pressure[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 7-14
[7]	Yao Zhanhu1, Yang Zhao2, Tian Yi1, Hu Huitao1.Key Construction Technology for the Nanjing Weisan Road River-Crossing Tunnel Project[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 15-23
[8]	Liu Guangfeng1, Chen Fangwei2, Zhou Zhi1, Zhang Shilong3, Liu Mingqiang1.Identification of Investment Risks for River-Crossing Tunnels Based on Grey Fuzzy Multi-Attribute Group Decision Making[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 41-48
[9]	Yao Zhanhu.Construction Risk Assessment for the Shield-Driven Section of the Nanjing Weisan Road River-Crossing Project[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 49-54
[10]	Zhang Boyang1, Zhao Xiaopeng1, Zhang Yaguo2, Chen Yu1.Risk Control for Saturated Hyperbaric Intervention in Slurry Shield Tunnelling[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 55-61
[11]	Li Xinyu, Zhang Dingli, Fang Qian, Song Haoran.On Water Burst Patterns in Underwater Tunnels[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(4): 24-31
[12]	Jiang Wei1, Liu Xin2, Liu Xian2, Luo Yao2, Yuan Yong2, Wang Shengnian3, Su Quanke4.Full-Scale Test of the Early Performance of a Factory-Prefabricated Immersed Tunnel[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(2): 135-142
[13]	Yan Tao1,2, Wang Mingnian1, Guo Chun1, Chen Hanbo1, Xie Wenqiang1.Key Techniques for the Diffused Oxygen Supply of an Extra-Long Highway Tunnel in a High-Altitude Area[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(2): 180-185
[14]	Pan Changping1,2,3, Wu Qing1,2,3, Zhai Mingang1,2,3, Zou Shun1,2,3.Dynamic Response Analysis of the Impact of a Rockfall on a Cantilever Shed Tunnel[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(2): 155-159
[15]	Lai Jinxing1,5, Qiu Junling1,5, Pan Yunpeng2, Cao Xiaojun3, Liu Chi1,4, Fan Haobo1,5.Comprehensive Monitoring and Analysis of Segment Cracking in Shield Tunnels[J]. MODERN TUNNELLING TECHNOLOGY, 2015,52(2): 186-191

Copyright 2010 by MODERN TUNNELLING TECHNOLOGY