TY - JOUR
T1 - Production scheduling for strategic open pit mine planning
T2 - A mixed-integer programming approach
AU - Letelier, Orlando Rivera
AU - Espinoza, Daniel
AU - Goycoolea, Marcos
AU - Moreno, Eduardo
AU - Muñoz, Gonzalo
N1 - Publisher Copyright:
Copyright: © 2020 INFORMS.
PY - 2020/9
Y1 - 2020/9
N2 - Given a discretized representation of an ore body known as a block model, the open pit mining production scheduling problem that we consider consists of defining which blocks to extract, when to extract them, and how or whether to process them, in such a way as to comply with operational constraints and maximize net present value. Although it has been established that this problem can be modeled with mixed-integer programming, the number of blocks used to represent real-world mines (millions) has made solving large instances nearly impossible in practice. In this article, we introduce a new methodology for tackling this problem and conduct computational tests using real problem sets ranging in size from 20,000 to 5,000,000 blocks and spanning 20 to 50 time periods. We consider both direct block scheduling and bench-phase scheduling problems, with capacity, blending, and minimum production constraints. Using new preprocessing and cutting planes techniques, we are able to reduce the linear programming relaxation value by up to 33%, depending on the instance. Then, using new heuristics, we are able to compute feasible solutions with an average gap of 1.52% relative to the previously computed bound. Moreover, after four hours of running a customized branch-and-bound algorithm on the problems with larger gaps, we are able to further reduce the average from 1.52% to 0.71%.
AB - Given a discretized representation of an ore body known as a block model, the open pit mining production scheduling problem that we consider consists of defining which blocks to extract, when to extract them, and how or whether to process them, in such a way as to comply with operational constraints and maximize net present value. Although it has been established that this problem can be modeled with mixed-integer programming, the number of blocks used to represent real-world mines (millions) has made solving large instances nearly impossible in practice. In this article, we introduce a new methodology for tackling this problem and conduct computational tests using real problem sets ranging in size from 20,000 to 5,000,000 blocks and spanning 20 to 50 time periods. We consider both direct block scheduling and bench-phase scheduling problems, with capacity, blending, and minimum production constraints. Using new preprocessing and cutting planes techniques, we are able to reduce the linear programming relaxation value by up to 33%, depending on the instance. Then, using new heuristics, we are able to compute feasible solutions with an average gap of 1.52% relative to the previously computed bound. Moreover, after four hours of running a customized branch-and-bound algorithm on the problems with larger gaps, we are able to further reduce the average from 1.52% to 0.71%.
KW - Column generation
KW - Cutting planes
KW - Heuristics
KW - Integer programming applications
KW - Open pit mining
KW - Production scheduling
UR - http://www.scopus.com/inward/record.url?scp=85090759850&partnerID=8YFLogxK
U2 - 10.1287/opre.2019.1965
DO - 10.1287/opre.2019.1965
M3 - Article
AN - SCOPUS:85090759850
SN - 0030-364X
VL - 68
SP - 1425
EP - 1444
JO - Operations Research
JF - Operations Research
IS - 5
ER -