Measurements of the current and size of the primary droplets of sprays generated by electrostatic atomization of a variety of liquids with different electrical conductivities, permittivities, liquid-gas surface tensions, densities and viscosities have been carried out. Scaling laws of the spray current as well as the charge and size of the droplets have been obtained from a theoretical model of the charge transport. Comparisons between experimental and theoretical results are good. We have found that there are two different behaviours strongly related to the viscosity and electrical conductivity of the liquid. The separation between both behaviours is governed by the dimensionless parameter delta(mu)delta(1/3) = [epsilon(0)(2) gamma(3)/(K-2 mu(3)Q)](1/3); Q, mu, K, gamma, and epsilon(0) the how rate, viscosity, electrical conductivity, surface tension of the gas-liquid interface and vacuum permittivity, respectively. For liquids with high enough conductivities and viscosities (delta(mu)delta(1/3) much less than 1), the spray current and droplet size are approximately given by I/I-0 = 6.2[Q/(beta - 1)(1/2)Q(0)](1/2) - 2.0 and d/(beta - 1)(1/3) d(0) = 1.6[Q/(beta - 1)(1/2) Q(0)](1/3) -1.0, where beta epsilon(0) is the liquid permittivity and I-0 = (epsilon(0) gamma(2)/rho)(1/2), d(0) = [gamma epsilon(0)(2)/(rho K-2)](1/3) and Q(0) = gamma epsilon(0)/rho K are a reference intensity, droplet size and flow rate, respectively. In the opposite limit, we have found I/I-0 = 11.0(Q/Q(0))(1/4) - 5.0 and d/d(0) = 1.2(Q/Q(0))(1/2) - 0.3. Comparisons with experimental data reported in the literature are also satisfactory.