This thesis is aimed to study the two-dimensional random-exchange spin-1/2 anti-ferromagnetic Heisenberg model on a triangular lattice. The characteristics of the system under the interactive influence of geometric frustration and bond randomness will be investigated. Using the method of tensor network, the quantum state and the Hamiltonian are expressed as the matrix product state and the matrix product operator, respectively. To numerically solve the problem, the density matrix renormalization group method is employed to optimally find the solutions of the ground state of the quantum system, the squared sublattice magnetization $m_s^2$, and the three-sublattice ferromagnetic order parameter $m_o$. It is shown that the order parameter is robust, and the inferred sequencing parameter should only disappear when the strength of the bond disorder is infinite. In the future, we expect to calculate the ground state properties for larger system sizes and will perform data fitting as well.