Doping of thermoreversible polymer gels with charged monomers provides a way to control phase separation and gelation conditions by coupling the properties of the gel with a tunable ionic environment. We analyze the dependence of the gelation and phase separation conditions on the amount of salt present using a mean field model of weakly charged associative polymers. The ions and co-ions present are explicitly considered at the mean field level, and we determine their concentrations in the different equilibrium phases when the system undergoes phase separation. For weak polymer charge, the entropic contributions of the ions to the free energy of the system play a central role in the determination of the location of phase equilibrium. In the simplest case, when the associative interaction responsible for gel formation is independent of the electrostatic interaction, the addition of salt changes the polymer equilibrium concentrations and indirectly changes the measurable swelling of the gel. We construct phase diagrams of these systems that exhibit the location of the coexistence region, the gel-sol boundary, and the location of the tie lines. We determine the swelling of the gel within the coexistence region. Our main result is that the effect of the salt on the properties of the weakly charged gel can be described through an extra contribution to the effective immiscibility parameter chi proportional to the square of the doping degree f (2) and to the inverse square of the added salt concentration s(-2).