Ecological-power generation dynamic mutual feedback regulation method for cascade reservoir group
A cascade reservoir and ecological technology, applied in the direction of circuit devices, AC network circuits, single-network parallel feeding arrangement, etc., can solve the problems of single target and poor adaptability
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Embodiment 1
[0067] like figure 1 As shown, a cascade reservoir group ecology-power generation dynamic mutual-feedback control method S100 includes the following steps:
[0068] Step S110: Make the power generation and water flow conditions meet the water quality water demand (W qua ), cut-off water demand (W dry ), water demand for sand flushing (W sed ), ecological water demand (W eco ) The spatio-temporal proportions of the four ecological standards are used as the objective function of the ecology-power generation mutual-feedback regulation model of the cascade reservoir group. The constraint set of the cascade reservoir group ecology-power generation mutual Equations, water storage limit constraints, power generation flow limit constraints, outflow flow constraints and power station output limit constraints;
[0069] Step S120: Using the improved non-dominated sorting genetic algorithm to obtain the optimal outflow of each reservoir at each time period from the ecology-power gener...
Embodiment 2
[0073] Based on Embodiment 1, the objective function of the cascade reservoir group ecology-power generation mutual-feedback control model is specifically:
[0074] (1) Power generation target:
[0075]
[0076] In the formula: E is the total generating capacity of the power station involved in the calculation of the dispatching period, kW h; I is the number of reservoirs; i is the serial number of the reservoir, i=1,2,...,I; T is the number of time slots during the dispatching period; t is the serial number of the time slot , t=1,2,...,T; P i,t is the output of reservoir i in period t, kW; Δt is the number of hours in period t, h.
[0077] (2) Ecological goals:
[0078] The ecological guarantee rate is defined as the time-space ratio of water flow conditions meeting the ecological standards of the above four water demand parameters. Taking the period division (month) of long-term hydropower dispatching as an example, the calculation formula of the ecological guarantee r...
Embodiment 1 Embodiment 2
[0086] Based on Embodiment 1 or Embodiment 2, the constraint conditions of the cascade reservoir group ecology-power generation mutual-feedback control model are as follows:
[0087] Water balance equation:
[0088] V i,t+1 =V i,t +3600×(I i,t -D i,t )Δt,i∈[1,I],t∈[1,T]
[0089] In the formula, V i,t is the storage capacity of reservoir i in period t, m 3 ; I i,t is the inflow flow of reservoir i in period t, m 3 / s.
[0090] Inbound flow balance equation:
[0091]
[0092] In the formula, q i,t , Q i,t , S i,t Respectively, the interval flow, power generation flow and abandoned water flow of reservoir i in time period t, m 3 / s;m i is the mth directly upstream reservoir of reservoir i; U i is the set of reservoirs directly upstream of reservoir i.
[0093] Outbound flow balance equation:
[0094] D. i,t =Q i,t +S i,t ,i∈[1,I],t∈[1,T]
[0095] Water storage limit constraints:
[0096]
[0097] In the formula, are the upper and lower limits of the ...
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