代写CEN 421 Construction Process Simulation帮做R语言
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Construction Process Simulation (CEN 421)
Coursework 1 Report
Coursework Description:
Develop a simulation model for the case study, which is the excavation project of a commercial building located in Suzhou, China. The excavation task was divided into 3 layers due to the depth requirements of the building’s first, second and third floor basement levels, which were 4.55 m, 3.8 m and 4.1 m respectively. When the case study was carried out, the excavation was on the third floor; therefore, the simulation model should be built for that floor only. The plane layout of the third floor is shown in Figure 1(a), where two roads and a long slope were established for trucks travelling down to the third floor and leaving the site; as a result of the road width, the number of trucks that could enter the site simultaneously was restricted to two. Furthermore, the zone division for the third floor was set to 6, as shown in Figure 1(b).
Figure 1. Third floor excavation: (a) Truck driving route; (b) Zone division
Onsite Data
Data were collected for the whole excavation activity, as shown in Table 1. The soil type was clay, and a dilation factor of 1.15 was applied to calculate the volume. Usually two, but sometimes three, working groups were observed on the site. Each group included one truck associated with two excavators loading the truck simultaneously. A total of 10 trucks (with a capacity of 20 m3) and 6 excavators (with a productivity rate of 100~150 m3/hour, and a bucket capacity of 1 m3) were arranged to carry out the work. The dump site was 25 km away from the construction site with trucks travelling at about 60 km/h. The running cost of machinery was assumed to be 200¥/day for excavators and 300¥/day for trucks based on the local average. The total volume of soil transported was 92429 m3.
Table 1. Data collected on site
Information Form. for construction site-1st |
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General Information (for floor 3) |
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Date |
2/11/2017 |
Temperature |
22℃ |
Humidity |
Change with Time |
|
Daily Work Time |
8a.m~11a.m/ 12a.m~10p.m (generally 12 hours/day) |
Soil Type |
Clay |
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How to get Vtot |
CAD(row) |
Floor H |
5.9 m |
Dilation Co |
1.15 (row) |
|
Total Volume of Floor 3 |
92429 m3 |
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BOQ for Excavation |
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For individual team |
Excavator |
3~4 |
Labor |
4 |
Trucks |
Around 10 |
No. of Team |
2~3 |
Team Productivity |
100 m3/hour |
|
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Remarks |
The actual works focus on zones |
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Appliance |
Excavator |
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1 |
Company |
PC210 |
Productivity |
100~150 m3/hour |
Cost |
200 ¥/d |
Down Time |
/ |
|
|
|||
2 (small) |
Company |
PC130 |
Productivity |
|
Cost |
200 ¥/d |
Down Time |
/ |
|
|
|||
Appliance |
Truck |
|||||
1 |
Company |
Hauling |
Productivity |
20~25m3 |
Cost |
300 ¥/d |
Down Time |
/ |
Speed at F |
60 km/h |
Speed at E |
|
|
2 (small) |
Company |
Hauling |
Productivity |
20~22 m3 |
Cost |
300 ¥/d |
Down Time |
/ |
Speed at F |
60 km/h |
Speed at E |
|
|
|
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Other Essential Information |
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Tmin for a truck from site to exit |
5~7 min |
Remarks |
Data were estimated based on the experience of the other two floors |
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Distance from site to Haul |
25 km |
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Pre T need before Excavation |
2~3 days |
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Normal trucks need per day |
~10+ |
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Route of truck |
Shown in Pictures |
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Space control |
Shown in Pictures |
Modelling requirement:
1) Develop a CYCLON simulation model in Simphony;
2) Run the simulation and produce a series of simulation results, including project duration, average cycle time, average utilization for resources, etc.
3) Space should be considered as a type of resources as well;
Based on the simulation model, figure out the optimized resource combination in terms of cost and duration, and find out:
1) The optimal number of trucks;
2) The optimal number of excavator serving one truck;
3) The optimal space resources, e.g., number of entry and exit.