Control method capable of promoting supercritical unit to participate in wind power dissipation
A supercritical unit and control method technology, applied in the direction of reducing/preventing power oscillation, etc., can solve the problems of supercritical unit anti-wind power disturbance ability and poor stability of operating parameters, so as to enhance anti-wind power disturbance ability, enhance frequency regulation ability, and improve wind power The effect of permeability
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specific Embodiment approach 1
[0048] Specific implementation mode one: the following combination Figure 2 to Figure 4 Describe this embodiment, a control method that can promote supercritical units to participate in wind power consumption described in this embodiment, the method includes:
[0049]Step 1. Periodically collect the wind power signal, use the collected wind power signal to construct a periodic boiler input acceleration signal BIR, and add the constructed boiler input acceleration signal BIR to the boiler load command BM;
[0050] Step 2. For the steam pressure deviation signal Δp T The absolute value of is compared with the threshold A; when |Δp T When |≤A, execute step 3; where, A is greater than 0;
[0051] when |Δp T When |>A, correct the boiler load command BM in step 1 to obtain the corrected boiler load command BM′, and output the corrected boiler load command BM′ to the boiler of the supercritical unit to realize the participation of the supercritical unit in wind power consumption...
specific Embodiment approach 2
[0053] Embodiment 2. This embodiment is a further description of the control method that can promote the supercritical unit to participate in wind power consumption described in Embodiment 1. In step 1, the method for constructing the boiler input acceleration signal BIR is:
[0054] Let the boiler input acceleration signal BIR be X(t), and the integral of the boiler input acceleration signal be I x , Y(t) is the main steam temperature signal, and the integral of the main steam temperature signal is I Y , the rising time of X(t) is 0~T 1 , the stationary time is T 1 ~T 2 , the fall time is T 2 ~T 3 ;
[0055] and expression for:
[0056]
[0057]
[0058] is the integral of the boiler input acceleration signal at time i; is the integral of the main steam temperature signal at time i; using I X1 and I X2 Calculate the value of the boiler input acceleration signal BIR time T 1 ~T 2 Amplitude when:
[0059]
[0060] Among them, t 1 for T 1 , t 2 for...
specific Embodiment approach 3
[0077] Specific embodiment three: This embodiment is a further description of the control method that can promote supercritical units to participate in wind power consumption described in specific embodiment one or two. In step one, the cycle of periodically collecting wind power signals is 32s .
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