Incorporating a demand charge in central plant optimization

What is claimed is: 1. An optimization and control system for a central plant configured to serve building energy loads, the optimization and control system comprising: a central plant controller configured to receive load prediction data indicating building energy loads for a plurality of time steps in an optimization period and utility rate data indicating a price of one or more resources consumed by equipment of the central plant to serve the building energy loads at each of the plurality of time steps, the central plant controller comprising: a high level optimization module configured to generate an objective function that expresses a total monetary cost of operating the central plant over the optimization period as a function of the utility rate data and an amount of the one or more resources consumed by the central plant equipment at each of the plurality of time steps; and a demand charge module configured to modify the objective function to account for a demand charge indicating a cost associated with a maximum power consumption during a demand charge period different from the optimization period, wherein modifying the objective function comprises applying a weighting factor to one of a demand charge term or a consumption term of the objective function, wherein the weighting factor equalizes the optimization period and the different demand charge period, the objective function comprising a summation of the consumption term and the demand charge term in which one of the consumption term or the demand charge term is multiplied by the weighting factor, wherein the consumption term comprises the amount of the one or more resources consumed by the central plant equipment at each time step of the optimization period multiplied by a cost per unit of the one or more resources, and the demand charge term comprises the maximum power consumption during the demand charge period multiplied by a cost per unit of power consumption; wherein the high level optimization module is configured to optimize the objective function over the demand charge period subject to a set of constraints to determine an optimal distribution of the building energy loads over multiple groups of the central plant equipment at each of the plurality of time steps, and configured to use the weighting factor to evaluate trade-offs between increasing the consumption term and increasing the demand charge term when optimizing the objective function; wherein the central plant controller is configured to control the central plant equipment according to a result of optimizing the objective function such that the central plant equipment operate to achieve the optimal distribution of the building energy loads at each of the plurality of time steps. 2. The optimization and control system of claim 1 , wherein the high level optimization module uses linear programming to generate and optimize the objective function. 3. The optimization and control system of claim 1 , wherein modifying the objective function to account for the demand charge comprises: adding the demand charge term to the objective function, wherein the demand charge term comprises a nonlinear function that selects the maximum power consumption during the demand charge period; and linearizing the demand charge term by adding one or more demand charge constraints to the set of constraints. 4. The optimization and control system of claim 1 , wherein: the objective function comprises a cost vector including cost variables that represent a monetary cost associated with each of the one or more resources consumed by the central plant equipment to serve the building energy loads at each of the plurality of time steps; and modifying the objective function to account for the demand charge comprises adding a demand charge rate to the cost vector. 5. The optimization and control system of claim 1 , wherein: the objective function comprises a decision matrix including load variables that represent an energy load for each of the multiple groups of the central plant equipment at each of the plurality of time steps; modifying the objective function to account for the demand charge comprises adding a demand charge variable to the decision matrix; and optimizing the objective function comprises determining optimal values for the variables in the decision matrix. 6. The optimization and control system of claim 5 , wherein modifying the objective function to account for the demand charge comprises adding one or more constraints on the demand charge variable to the set of constraints for each of the plurality of time steps in the demand charge period; wherein the constraints on the demand charge variable for each time step require the demand charge variable to be greater than or equal to a total energy consumption at the time step. 7. The optimization and control system of claim 6 , wherein the total energy consumption at a time step is a total electric power consumed by the central plant equipment and one or more buildings served by the central plant equipment at the time step. 8. The optimization and control system of claim 6 , wherein the demand charge constraint for each time step requires the demand charge variable to be greater than or equal to a value of the demand charge variable at a previous time step in the demand charge period. 9. The optimization and control system of claim 1 , wherein the weighting factor comprises at least one of: a ratio of a duration of the demand charge period to a duration of the optimization period applied to the consumption term of the objective function; and a ratio of the duration of the optimization period to the duration of the demand charge period applied to the demand charge term of the objective function. 10. A method for incorporating a demand charge in an optimization and control process for a central plant, the method comprising: receiving, at a central plant controller, load prediction data indicating building energy loads for a plurality of time steps in an optimization period and utility rate data indicating a price of one or more resources consumed by equipment of the central plant to serve the building energy loads at each of the plurality of time steps; generating, by a high level optimization module, an objective function that expresses a total monetary cost of operating the central plant over the optimization period as a function of the utility rate data and an amount of the one or more resources consumed by the central plant equipment at each of the plurality of time steps; modifying, by a demand charge module, the objective function to account for a demand charge indicating a cost associated with a maximum power consumption during a demand charge period different from the optimization period, wherein modifying the objective function comprises applying a weighting factor to one of a demand charge term or a consumption term of the objective function, wherein the weighting factor equalizes the optimization period and the different demand charge period, the objective function comprising a summation of the consumption term and the demand charge term in which one of the consumption term or the demand charge term is multiplied by the weighting factor, wherein the consumption term comprises the amount of the one or more resources consumed by the central plant equipment at each time step of the optimization period multiplied by a cost per unit of the one or more resources, and the demand charge term comprises the maximum power consumption during the demand charge period multiplied by a cost per unit of power consumption; optimizing, by the high level optimization module, the objective function over the demand charge period subject to a set of constraints to d