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Procedia Engineering 73 ( 2014 ) 150 – 159
1877-7058 © 2014 Published by Elsevier Ltd. Open access under CC BY-NC-ND license. Selection and peer-review under responsibility of Geological Engineering Drilling Technologydoi: 10.1016/j.proeng.2014.06.183
ScienceDirectAvailable online at www.sciencedirect.com
Geological Engineering Drilling Technology Conference (IGEDTC), New International Convention Exposition Center Chengdu Century City on 23rd-25th May 2014
Research and Development on Geological Core Drilling Computer Aided Design System
Yuanbiao Hua,*, Tianqing Wanga, Wenjian Zhub
aSchool of Engineering and Technology, China University of Geosciences, Beijing, 100083, P.R.China bBeijing Institute of Exploration Engineering, Beijing, 100083, P.R.China
Abstract
On the request of the current level of the geological core drilling design, refer to oil drilling design software, a geological core drilling computer aided design system was developed by means of advanced web design technology. The system covers all procedures of geological core drilling design, and presets reference value according to system database information, and automatically draws geological column and borehole columnar section according to the user design information, and finally produces overall and standard design report. The development technology is based on ZK and Hibernate framework with MVC and MVVM model. Consequently, the system will be easy to be used and maintained, and will contribute to the geological core drilling design information exchange and share online. © 2014 The Authors. Published by Elsevier Ltd. Selection and peer-review under responsibility of Geological Engineering Drilling Technology.
Keywords: Core Drilling, Computer Aided Design, Html5
1. Introduction
With the rapid development of computer technology, computer software is applied in all walks of life. In oil drilling industry, a lot of drilling engineering design software are developed and produce enormous economic and social benefits, and greatly drive the development of the drilling engineering. However, in core drilling industry, there isn’t the applicable geological core drilling design software. In China, the geological core drilling is still
* Yuanbiao Hu. Tel.: +08613811999982; fax: +0861082321887. E-mail address: [email protected]
© 2014 Published by Elsevier Ltd. Open access under CC BY-NC-ND license. Selection and peer-review under responsibility of Geological Engineering Drilling Technology
151 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
designed by manual. The efficiency of manual design and drawing is very low. With the increasingly development of drilling technology, the manual design method can’t meet the requirements. Therefore, in order to further improve the level of geological core drilling design, the research and development on geological core drilling computer aided design is very necessary.
2. System Functions
2.1. Function Design
According to the Industry Standard of Geological Core Drilling Procedures issued by the ministry of land and resources of the People's Republic of China in 2010, and the current market demand for geological core drilling design, there are the following functions in the geological core drilling aided design system:
Design the geological core drilling design basic procedures, including geological information input, borehole columnar section design, bottom hole assembly (BHA) design, drilling parameter design, mud design, cementing design, equipment selection, accident prevention, construction organization and management, construction schedule, construction budget, and report output. Automatically plot the borehole columnar section and drilling progress chart. Real-time output the geological core drilling design report online. Import example documents. Manage the user information.
2.2. System Structure
Fig. 1 System Structure
As shown in fig. 1, the system has the database module and system functions module. Database Module
Basic information database, including geological rock database, drilling technology database, drilling equipment database, cementing database, downhole accident information, is the main basis of drilling system aided design. User information database, including the every user’s basic register information and drilling designed data. Design information database which stores each design data, is used to import and export design example and browse the design result.
System function module, which has 14 functions, will be discussed later individually.
152 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
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153 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
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154 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
3.5.2A
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Fig. 4 Formati
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Fig. 5 Mud
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Fig. 6 Mud
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Performance
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155 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
3.6.
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This function ign informatiohe casing dimtion, and autocement. Final
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Fig. 8 Accid
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156 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
3.9.
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There are four the manage r.
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rilling expensets, which can he borehole c
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157 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
3.12
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With the mainmplate, in whic
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In order to fue system providate the designmple docume
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nstream reporch the all kindem automatica, word or exce
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urther improveides the designed drilling ent library, theer can selectehole columna
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e user can impt the importear section, bot
Fig. 10 Cons
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struction Budget
the system prll be automatinding single-h
e system provry, in which thnds the matchple document on in the exemble, etc. wh
rovides a set oically insertedhole core drill
vides the examhe user can lo
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xample documhich are descri
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mple documenook up, compaexample docueate the new dment, such asibed above.
core drilling esponding poseport, which c
nt import funare, import, sa
ument in the ddesign documeas basic geolo
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nction. ave or design ent. In ogical
158 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
3.14
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4. User Inform
n this function
he Key Techn
The key technoedule chart. Using Html5 ahod of the can
The followingsing informatio
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ology of the s
and JavaScripnvas gets the gs are the stepon: ed information
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ement
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system is the
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n of the boreh
Fig. 11 Example
ister informati
g. 12 User Inform
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he system firxt, on which thautomatically
hole columnar
Document Impo
ion and his ow
mation Managem
hnology of the
rst defines thehe graphic is dy the borehole
r section and f
ort
wn designed d
ment
e borehole col
e canvas, thendrawing. e columnar se
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n by means o
ction accordin
m backend dat
ples.
n and constru
of the getCont
ng to the desi
tabase.
uction
text()
igned
159 Yuanbiao Hu et al. / Procedia Engineering 73 ( 2014 ) 150 – 159
Define and set the canvas. Import the pic_base.js file, in which there are great amounts of drawing methods compiled by the author. Draw the coordinate axes, and then fill the corresponding area with the rock legend. Draw the borehole outline, and dimension the borehole size. Draw the casing outline, and dimension the casing size. Output and save the graphic with the data stream to the specified location.
Conclusions
The paper presents a geological core drilling computer aided design system, which was developed by means of advanced web design technology. The system covers all procedures of geological core drilling design, and presets reference value according to system database information, and automatically draws geological column and borehole columnar section according to the user design information, and finally produces overall and standard design report. The development technology is based on ZK and Hibernate framework with MVC and MVVM model. Consequently, the system will be easy to be used and maintained, and will contribute to the geological core drilling design information exchange and share online. It solves the problems of manual design of the geological core drilling, low design efficiency, and lack of standardization of the drawing and design report. It significantly improves the design efficiency, shortens the design periods, and reduces the design cost. It can realize the standardization, normalization and informatization of the geological core drilling design in the whole nation. Consequently, there is a bright prospect for the geological core drilling computer aided design system.
Acknowledgements
This work was supported by the National High Technology Research and Development Program of China (863 Program)(Grant No. 2014AA06A614), the National Natural Science Foundation of China(No. 51204149), the Fundamental Research Funds for the Central Universities (No. 2-9-2012-45), and the Open Project Fund of the Key Laboratory on Deep GeoDrilling Technology of the Ministry of Land and Resources (No. NLSD201213).
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