In this paper, the wakes behind a square cylinder were simulated using two kinds of different turbulence models for the eddy viscosity concept such as the zero- and the one-equation model in which the former is the mixing length model and the latter is the k-equation model. For comparison between numerical and analytical solutions, we employed three skill assessments: the correlation coefficient(r) for the similarity of the wake shape, the error of maximum velocity difference(EMVD) for the accuracy of wake velocity and the ratio of drag coefficient(RDC) for the pressure distribution around the structure. On the basis of the numerical results, the feasibility of each model for wake simulation was discussed and a suitable value for the empirical constant was suggested in these turbulence models. The zero-equation model, known as the simplest turbulence model, overestimated the EMVD and its absolute mean error(AME) for r, EMVD and RDC was ranging from 20.3 % to 56.3 % for all test. But the AME by the one-equation model was ranging from 3.4 % to 19.9 %. The predicted values of the one-equation model substantially agreed with the analytical solutions at the empirical mixing length scale L=0.6b1/2 with the AME of 3.4 %. Therefore it was concluded that the one-equation model was suitable for the wake simulation behind a square cylinder when the empirical constant for eddy viscosity would be properly chosen.

이송항에는 5차 보간다항식을 사용하는 Holly-Pressmann 기법을, 확산항에는 Hobson 등이 제안한 양해법을 사용하는 연산자 분리기법을 사용하여 1차원 이송-확산방정식의 수치모형을 제안하였다. 제안된 모형을 검정하기 위하여 일정한 유속과 종확산계수를 갖는 순간적으로 부하된 오염원의 경우와 상류단에 연속적인 오염원을 갖는 경우에 대하여 본 모형의 해를 해석해와 기존의 모형으로부터 구한 해를 비교검토하였다. Courant 수와 Peclet 수를