You can use the least-square optimization function in scipy to fit any arbitrary function to another. In case of fitting a sin function, the 3 parameters to fit are the offset ('a'), amplitude ('b') and the phase ('c').
As long as you provide a reasonable first guess of the parameters, the optimization should converge well.Fortunately for a sine function, first estimates of 2 of these are easy: the offset can be estimated by taking the mean of the data and the amplitude via the RMS (3*standard deviation/sqrt(2)).
This leads to the following code:
import numpy as np
from scipy.optimize import leastsq
import pylab as plt
N = 1000 # number of data points
t = np.linspace(0, 4*np.pi, N)
data = 3.0*np.sin(t+0.001) + 0.5 + np.random.randn(N) # create artificial data with noise
guess_a = np.mean(data)
guess_b = 3*np.std(data)/(2**0.5)
guess_c = 0
# we'll use this to plot our first estimate. This might already be good enough for you
data_first_guess = guess_b*np.sin(t+guess_c) + guess_a
# Define the function to optimize, in this case, we want to minimize the difference
# between the actual data and our "guessed" parameters
optimize_func = lambda x: x*np.sin(t+x) + x - data
est_a, est_b, est_c = leastsq(optimize_func, [guess_a, guess_b, guess_c])
# recreate the fitted curve using the optimized parameters
data_fit = est_a*np.sin(t+est_c) + est_b
plt.plot(data_fit, label='after fitting')
plt.plot(data_first_guess, label='first guess')
Edit: I assumed that you know the number of periods in the sine-wave. If you don't, it's somewhat trickier to fit. You can try and guess the number of periods by manual plotting and try and optimize it as your 4th parameter.