CN108120878A - The D.C. resistance choosing method and system of a kind of Complicated Distribution Network complex optimum device - Google Patents

Abstract

The invention discloses the D.C. resistance choosing methods and system of a kind of Complicated Distribution Network complex optimum device.The D.C. resistance choosing method of the present invention includes：1) equivalent circuit under positive sequence, negative phase-sequence, three sequence fundamental frequency equivalent circuit of zero sequence and the sample frequency of Complicated Distribution Network complex optimum device is built；2) fundamental frequency of fault point distribution system and positive sequence under sample frequency, negative phase-sequence, three sequence equivalent circuit of zero sequence are built；3) relational expression between fault current and D.C. resistance is calculated；4) lower limiting value of D.C. resistance is determined；5) relational expression between the electric current and D.C. resistance of trouble point sample frequency is calculated；6) upper limit value of D.C. resistance is determined；7) relation according to lower limiting value and upper limit value and between the two obtains D.C. resistance.The D.C. resistance resistance value that the present invention chooses can take into account the effective extinguishing arc of distribution system and accurate route selection, can effectively promote the control performance of complex optimum device, realize its substitution effect to arc suppression coil.

Description

Direct current resistance selection method and system of complex power distribution network comprehensive optimization device

Technical Field

The invention belongs to the technical field of flexible power distribution networks, and particularly relates to a direct current resistance selection method and a direct current resistance selection system of a complex power distribution network comprehensive optimization device.

Background

In recent years, many new electrical devices based on power electronic technology appear in power supply and distribution systems, and these nonlinear loads have nonlinear and impulsive characteristics, which not only cause the distortion of bus voltage and current waveforms in the system, but also cause the phenomena of flicker, fluctuation and three-phase imbalance of the bus voltage of the power grid, cause serious pollution to the power supply quality, and affect the economic and safe operation of the electrical devices in the power grid. The voltage source type converter has excellent control operation performance, and is widely used as an active filter, a reactive compensator and the like at present to optimize the quality of electric energy and alleviate the problems.

With the enlargement of the distribution network scale and the increase of cable lines, the capacitance current of the distribution network seriously exceeds the standard, and the requirement of the operation of the power grid can not be met by a neutral point ungrounded mode. At present, most of 10kV power distribution networks in China adopt an arc suppression coil grounding mode to suppress fault current. However, due to the compensation effect of the arc suppression coil, the characteristics of zero-sequence currents of a fault line and a non-fault line in a steady state may be the same, which greatly increases the difficulty of fault line selection, and leads to inaccurate line selection and false alarm phenomena. Meanwhile, the traditional arc suppression coil grounding mode cannot automatically and continuously follow the parameter change of a power grid to carry out optimal adjustment, and cannot enable the residual current of a fault point to be in a minimum state at any time.

The voltage source type converter under the direct current side grounding mode has zero sequence voltage and current regulation capacity, fully utilizes equipment such as an active filter and the like, adopts time-sharing regulation means (for example, when the converter is in normal operation, the converter is used for filtering and optimizing the electric energy quality, and when the converter is in fault, control means such as zero sequence current and the like are used for arc suppression and line selection), can enable a power distribution network to remove the use of an arc suppression coil, and only one converter is used for realizing the functions of the active filter and the arc suppression coil. The voltage source type converter with multiple functions can be called a complex power distribution network comprehensive optimization device. The method can reduce the equipment investment cost, can also compensate the fault current by utilizing the quick adjustment capacity of the zero-sequence current of the converter to maintain the minimum state of the fault current, and can effectively improve the line selection accuracy by injecting a voltage current signal with certain frequency by utilizing a means similar to an S injection method.

The resistance value of the direct current resistor influences the arc extinction effect of the converter and the line selection accuracy effect under the condition of certain frequency signal injection. In order to effectively suppress the instantaneous ground current and overvoltage of a single-phase ground fault and simultaneously consider the line selection accuracy of a system under the condition of injecting a certain frequency signal, parameter design needs to be carried out on the resistance value of a direct current resistor.

Disclosure of Invention

Aiming at the problems of the direct current resistance of the converter, the invention provides the direct current resistance selection method of the complex power distribution network comprehensive optimization device, which can realize effective arc extinction, inhibit the single-phase grounding short-circuit current within a specified range, meet the high-accuracy line selection requirement of the system and provide conditions for the good control performance of the comprehensive optimization device.

Therefore, the invention adopts the following technical scheme: a direct current resistance selection method of a complex power distribution network comprehensive optimization device is characterized in that the complex power distribution network comprehensive optimization device is a transformer-free hybrid MMC, the alternating current side of the hybrid MMC is directly connected with a substation bus through an alternating current breaker, and a connection transformer is not arranged in the middle of the hybrid MMC; positive pole of DC side and capacitor C₁Connected with the negative electrode of the DC side and a capacitor C₂Connected to a capacitor C₁Another terminal of (1) and a capacitor C₂Is connected to the other end of the resistor and is simultaneously connected to a direct current resistor R₀Connected, DC resistance R₀The other end of the first and second electrodes is directly grounded;

the direct current resistance selection method comprises the following steps:

1) positive sequence, negative sequence and zero sequence three-sequence base frequency equivalent circuit and sampling frequency f for constructing complex power distribution network comprehensive optimization device_sThe equivalent circuit is formed by connecting an equivalent voltage source and an equivalent impedance in series;

2) selecting n (n is an integer) typical single-phase earth fault points, and constructing the fundamental frequency and the sampling frequency f of the power distribution system at the fault points_sA lower positive sequence, negative sequence and zero sequence equivalent circuit;

3) setting different fault ground resistances R_fCalculating to obtain fault current I according to the positive sequence, negative sequence and zero sequence base frequency equivalent circuit at the fault point_fAnd a direct current resistance R₀The relation between;

4) based on maximum fault current not exceeding maximum short-circuit current I_f0Determining a lower limit value R of the direct current resistance_min；

5) According to sampling frequency f at fault point_sCalculating a positive sequence, a negative sequence and a zero sequence equivalent circuit to obtain a fault point sampling frequency f_sCurrent of (I)_fsAnd a direct current resistance R₀The relation between;

6) based on fault grounding resistance being smaller than set resistance R_f0And the frequency of the inflow fault point is f_sIs not less than the minimum current I of the effective signal_fs0Determining an upper limit value R of the direct current resistance_max；

7) R obtained according to step 4)_minR obtained in step 6)_maxAnd the relation between the two to obtain the direct current resistance R₀。

As a complement to the above-mentioned method of selecting the dc resistance, in step 1),

the positive sequence fundamental frequency equivalent voltage source is e⁺Positive sequence fundamental frequency equivalent impedance of Z⁺(ii) a The equivalent voltage source of the negative sequence fundamental frequency is 0, and the equivalent impedance of the negative sequence fundamental frequency is Z^-(ii) a The zero-sequence fundamental frequency equivalent voltage source is 0, and the zero-sequence fundamental frequency equivalent impedance is Z⁰(ii) a Wherein,ω₀＝2πf₀，f₀50 Hz; j represents the imaginary unit; r and L are each independentlyBridge arm equivalent resistance and inductance; r₀Is a direct current resistance; c_dIs a capacitor C₁And C₂The capacitance value of (a); e.g. of the type⁺The positive-sequence fundamental frequency voltage output by the MMC is obtained by the MMC according to the control of a power distribution system;

positive sequence f_sFrequency equivalent voltage source of 0, positive sequence f_sFrequency equivalent impedance ofNegative sequence f_sFrequency equivalent voltage source of 0, negative sequence f_sFrequency equivalent impedance ofZero sequence f_sA frequency equivalent voltage source ofZero sequence f_sFrequency equivalent impedance ofWherein,ω_s＝2πf_s，f_s＝220Hz；frequency of output for MMC_sThe zero sequence voltage of (2) is obtained by controlling the MMC according to the power distribution system.

As a complement to the above-mentioned dc resistance selection method, in step 2),

the positive sequence fundamental frequency equivalent voltage source at the fault point is k₁₁E_s+k₁₂e⁺Positive sequence fundamental frequency equivalent impedance is k₁₃+k₁₄Z⁺(ii) a The negative sequence fundamental frequency equivalent voltage source is 0, and the positive sequence fundamental frequency equivalent impedance is k₁₃+k₁₄Z^-(ii) a The zero-sequence fundamental frequency equivalent voltage source is 0, and the zero-sequence fundamental frequency equivalent impedance is k₁₅+k₁₆Z⁰(ii) a Wherein Es isDistribution network supply voltage, k₁₁、k₁₂、k₁₃、k₁₄、k₁₅、k₁₆The fault location is determined by the structure and parameters of the power distribution network and is constant for the specified fault location;

positive sequence f at fault point_sFrequency equivalent voltage source of 0, positive sequence f_sFrequency equivalent impedance ofNegative sequence f_sFrequency equivalent voltage source of 0, negative sequence f_sFrequency equivalent impedance ofZero sequence f_sA frequency equivalent voltage source ofZero sequence f_sFrequency equivalent impedance ofk_s1、k_s2、k_s3、k_s4、k_s5It is a constant for a given fault location, determined by the distribution network structure and parameters.

As a supplement to the above-mentioned method of selecting the dc resistance, in step 3), the fault current I_fAnd a direct current resistance R₀The relationship between them is as follows:

wherein,k₁₇and are constants related to the power distribution network structure and parameters.

As a complement to the above-mentioned dc resistance selection method, in step 4),

for the firstI fault points, I is more than or equal to 1 and less than or equal to n, and the maximum short-circuit current I_f0Under the limitation of (3), obtaining a direct current resistance R₀Lower limit value ofWherein I_f0Taking out the mixture of 30A and 30B,

selectingThe medium maximum value is the direct current resistance R₀Lower limit value R of_min，

As a supplement to the above-mentioned method of selecting the direct current resistance, in step 5), the current I_fsAnd a direct current resistance R₀The relationship between them is as follows:

wherein,k_s6and are constants related to the power distribution network structure and parameters.

As a complement to the above-mentioned dc resistance selection method, in step 6),

ith fault point, R₀Upper limit value ofComprises the following steps:

wherein,set to less than 10% of the rated voltage of the fundamental frequency; r_f0The selection relates to the effective grounding problem of the direct current side of the device, and 100 omega, I is taken_fs0Taking 1A; selectingThe minimum value is the DC resistance R₀Upper limit value R of_max，

As a complement to the above-mentioned dc resistance selection method, in step 7),

if R is_max≥R_minThen the direct current resistance R₀In { R_min，R_maxSelecting within the range; the selection bias is R based on the further requirements of fault current control and line selection accuracy_maxOr R_min；

If R is_max<R_minThen in step 6) by decreasing R_f0Calculation of R_maxParameter until R is satisfied_max≥R_minUnder the condition of (1) R₀Is set as R_minOr R_maxAnd recording the corresponding R_f0. In this case, the following meanings are included: in the R₀If the grounding resistance is less than the corresponding R_f0Otherwise, other existing line selection methods are required to participate in line selection calculation together so as to ensure the line selection accuracy.

As a supplement to the direct current resistance selection method, each bridge arm of the mixed MMC is formed by cascading a plurality of submodules, the bridge arm reactors are connected in series, the types of the submodules in the bridge arms are HBSM and FBSM, the number ratio of the submodules in the two types is 1:1, and a driving circuit board of each submodule is powered by capacitance voltage of the corresponding submodule.

The invention also provides a direct current resistance selection system of the complex power distribution network comprehensive optimization device, wherein the complex power distribution network comprehensive optimization device is a transformer-free hybrid MMC; the direct current resistance selection system comprises:

equivalent circuit first construction unit: positive sequence, negative sequence and zero sequence three-sequence base frequency equivalent circuit and sampling frequency f for constructing complex power distribution network comprehensive optimization device_sThe equivalent circuit is formed by connecting an equivalent voltage source and an equivalent impedance in series;

the equivalent circuit second construction unit: selecting n typical single-phase earth fault points, and constructing the fundamental frequency and the sampling frequency f of the power distribution system at the fault points_sA lower positive sequence, negative sequence and zero sequence equivalent circuit;

a first relational expression calculation unit: setting different fault ground resistances R_fCalculating to obtain fault current I according to the positive sequence, negative sequence and zero sequence base frequency equivalent circuit at the fault point_fAnd a direct current resistance R₀The relation between;

a direct current resistance lower limit value determination unit: based on maximum fault current not exceeding maximum short-circuit current I_f0Determining a lower limit value R of the direct current resistance_min；

A second relational expression calculation unit: according to sampling frequency f at fault point_sCalculating a positive sequence, a negative sequence and a zero sequence equivalent circuit to obtain a fault point sampling frequency f_sCurrent of (I)_fsAnd a direct current resistance R₀The relation between;

a direct current resistance upper limit value determination unit: based on fault grounding resistance being smaller than set resistance R_f0And the frequency of the inflow fault point is f_sIs not less than the minimum current I of the effective signal_fs0Determining an upper limit value R of the direct current resistance_max；

A direct current resistance obtaining unit: according to R_min、R_maxAnd the relation between the two to obtain the direct current resistance R₀。

The invention has the following beneficial technical effects:

(1) the direct-current resistance value selected by the method can give consideration to effective arc extinction and accurate line selection of a power distribution system, can effectively improve the control performance of the comprehensive optimization device, and realizes the substitution effect of the comprehensive optimization device on the arc extinction coil.

(2) The invention has strong universality and is suitable for power distribution networks with different network topology structures.

Drawings

FIG. 1 is a schematic diagram of a power distribution system including an integrated optimization device in accordance with an embodiment of the present invention;

FIG. 2 is a flow chart of a method for selecting a ground resistor according to an embodiment of the present invention;

fig. 3 is an equivalent model diagram of a hybrid MMC in an embodiment of the invention.

Detailed Description

To describe the present invention more specifically, the following detailed description of the technical solution and the related principles of the present invention is made with reference to the drawings and the detailed description of the present invention.

Example 1

The embodiment provides a direct current resistance selection method of a complex power distribution network comprehensive optimization device.

As shown in FIG. 1, the integrated optimization device adopts a transformerless hybrid MMC (MMC belongs to a voltage source type converter), and the AC side of the hybrid MMC is connected with a transformer through an AC breaker QThe power station buses are directly connected, and no connecting transformer is arranged in the middle; positive pole of DC side and capacitor C₁Connected with the negative electrode of the DC side and a capacitor C₂Connected to a capacitor C₁Another terminal of (1) and a capacitor C₂Is connected to the other end of the resistor and is simultaneously connected to a direct current resistor R₀Connected, DC resistance R₀And the other end of the same is directly grounded.

The hybrid MMC adopts a three-phase six-bridge arm structure, each bridge arm is formed by cascading n submodules and is connected with a bridge arm reactor in series, wherein the number n of the submodules is determined by direct current voltage, alternating current voltage, submodule voltage and bridge arm redundancy. Each bridge arm comprises a half-bridge sub-module (HBSM) and a full-bridge sub-module (FBSM), the number ratio of the two sub-modules is 1:1, and a driving circuit board of each sub-module is powered by capacitor voltage of the sub-module. The HBSM comprises two IGBTs (T)₁And T₂) Two antiparallel diodes (D)₁And D₂) And a capacitor C; the FBSM includes four IGBTs (T)₁-T₄) Four anti-parallel diodes (D)₁-D₄) And a capacitor C.

In the invention, the selection of the direct current resistor needs to simultaneously consider the ground current suppression and f at the moment of single-phase ground fault_s(f_sTypically chosen to be a value intermediate N times and N +1 times the fundamental frequency, such as 220Hz, where N is an integer) frequency signal injection to the line selection accuracy, i.e., arc suppression and option capability, of the lower system. Therefore, the resistance of the direct current resistor needs to be restricted from both arc extinction and line selection, so as to obtain a proper direct current resistor. Fig. 2 shows the specific steps of the ground resistance selection method, which are respectively:

the first step is as follows: positive sequence, negative sequence and zero sequence three-sequence base frequency equivalent circuit and frequency f for constructing comprehensive optimization device of power distribution network_sAnd the equivalent circuit is formed by connecting an equivalent voltage source and an equivalent impedance in series.

The second step is that: selecting a plurality of typical single-phase earth fault points, and constructing the fundamental frequency and the frequency f of the system at the fault points_sLower rightSequence, negative sequence, zero sequence equivalence circuit.

The third step: setting different fault ground resistances R_fCalculating to obtain fault current I according to the positive sequence, negative sequence and zero sequence base frequency equivalent circuit at the fault point_fAnd a direct current resistance R₀The relation between them.

The fourth step: based on maximum fault current not exceeding limit value I_f0Determining a lower limit value R of the direct current resistance_min。

The fifth step: according to frequency f at fault point_sCalculating the positive sequence, negative sequence and zero sequence equivalent circuit to obtain a fault point frequency f_sCurrent of (I)_fsAnd a direct current resistance R₀The relation between them.

And a sixth step: based on fault grounding resistance being smaller than set resistance R_f0And the frequency of the inflow fault point is f_sIs not less than the minimum current I of the effective signal_fs0Determining an upper limit value R of the direct current resistance_max。

The seventh step: r obtained according to the fourth step_minR obtained in the sixth step_maxAnd the relation between the two to obtain the direct current resistance R₀。

In the first step, fig. 3 shows an equivalent model of the hybrid MMC, and the following equations can be listed

U_dp-U_dn＝U_dc(3)

i_sj＝i_jn-i_jp(4)

Wherein u is_jAnd i_sj(j ═ a, b, c) represents the alternating voltage and alternating current on the alternating current outlet side of the MMC, i_jpAnd i_jnIs j-phase upper and lower bridge arm current, u_jpAnd u_jnIs the output voltage of the sub-module group connected with the upper bridge arm and the lower bridge arm in series of j phase, U_dpAnd U_dnIs a positive DC voltage and a negative DC voltage, U_dcIs a DC interpolar voltage u_oThe voltage of a neutral point on the direct current side is R and L are equivalent resistance and inductance of a bridge arm respectively.

By substituting the equations (1) to (4), the following expression can be obtained:

wherein,

substituting j ═ a, b, c into the above formula, the abc triphase equation can be obtained, and the equation can be used

The mathematical models that can be obtained for positive, negative and zero sequences are:

wherein the superscripts "+", "-" and "0" represent positive, negative and zero sequence components, respectively, as can be seen from the structure of figure 3,

u_o＝(i_dcp+i_dcn)R₀(10)

wherein, C_dIs a capacitor C₁And C₂The capacitance value of (2). According to the kirchhoff's current theorem, the total current flowing in is equal to the total current flowing out, there

The positive sequence, negative sequence and zero sequence fundamental frequency equivalent models can be obtained by substituting equations (10) - (13) into equations (7) - (9) and adopting Fourier transform.

Wherein,ω₀＝2πf₀，f₀the equivalent impedance of the positive and negative sequences is the same at 50 Hz.

Under the condition of normal operation, the comprehensive optimization device of the power distribution network only outputs a positive sequence voltage component, and the negative sequence and the zero sequence control are put into use after the system fails. Then it can be found that: the positive sequence fundamental frequency equivalent voltage source is e⁺Positive sequence fundamental frequency equivalent impedance of Z⁺(ii) a The equivalent voltage source of the negative sequence fundamental frequency is 0, and the equivalent impedance of the negative sequence fundamental frequency is Z^-(ii) a The zero-sequence fundamental frequency equivalent voltage source is 0, and the zero-sequence fundamental frequency equivalent impedance is Z⁰。

In the same way, the injection frequency of the comprehensive optimization device to the power distribution network is f_sThe frequency f can be obtained similarly when the zero sequence current signal is obtained_sThe following equivalent model.

Wherein,ω_s＝2πf_s，f_s220 Hz. Also, the positive and negative sequence have the same equivalent impedance.

Due to f_sThe current signal is zero sequence component, and there is no positive sequence power supply and negative sequence power supply under this frequency, so can obtain: positive sequence f_sFrequency equivalent voltage source of 0, positive sequence f_sFrequency equivalent impedance ofNegative sequence f_sFrequency equivalent voltage source of 0, negative sequence f_sFrequency equivalent impedance ofZero sequence f_sA frequency equivalent voltage source ofZero sequence f_sFrequency equivalent impedance of

In the second step, typically n fault points are selected, where n is an integer. Because the distribution network is a radial structure, typical positions such as the head end, the tail end and the contact point of the feeder line are generally selected. Then, for each fault point, constructing a system fundamental frequency equivalent circuit and f at the fault point_sAnd a frequency equivalent circuit.

In the construction process, the equivalent model of the comprehensive optimization device obtained in the first step is analogized to electric power elements such as transformers and distribution lines, the sequence component decomposition calculation is carried out on the whole power distribution system except the fault point by using a symmetric component method according to the existing traditional electric power analysis means, and finally, the positive sequence fundamental frequency equivalent voltage source k at the fault point can be obtained₁₁E_s+k₁₂e⁺Positive sequence fundamental frequency equivalent impedance is k₁₃+k₁₄Z⁺(ii) a The negative sequence fundamental frequency equivalent voltage source is 0, and the positive sequence fundamental frequency equivalent impedance is k₁₃+k₁₄Z^-(ii) a The zero-sequence fundamental frequency equivalent voltage source is 0, and the zero-sequence fundamental frequency equivalent impedance is k₁₅+k₁₆Z⁰. Wherein Es is the power supply voltage of the power distribution network, k₁₁、k₁₂、k₁₃、k₁₄、k₁₅、k₁₆Depending on the distribution network configuration and parameters, it may be considered constant for a given fault location.

Similarly, the frequency f can be obtained_sNext, the equivalent model of each sequence component at the fault point, wherein the positive sequence f at the fault point_sFrequency equivalent voltage source of 0, positive sequence f_sFrequency equivalent impedance ofNegative sequence f_sFrequency equivalent voltage source of 0, negative sequence f_sFrequency equivalent impedance ofZero sequence f_sA frequency equivalent voltage source ofZero sequence f_sFrequency equivalent impedance ofk_s1、k_s2、k_s3、k_s4、k_s5Depending on the distribution network configuration and parameters, it may be considered constant for a given fault location.

In the third step, the single-phase earth fault resistor R_fMay correspond to different resistance values such as 0 Ω,1 Ω, 10 Ω, 100 Ω, etc. The method comprises the following steps of (1) utilizing a composite sequence network equation of the single-phase grounding short circuit provided in the existing asymmetric short circuit calculation method:

the fault current I can be calculated by combining the fundamental frequency equivalent model provided in the second step_fAnd a direct current resistance R₀The relation between them.

Wherein,it can be seen that k₁₇And are constants related to the power distribution network structure and parameters.

In the fourth step, as can be seen from the formula (22), e is divided⁺，R_fAnd R₀The three variables and the rest parameters are determined by the grid structure and the parameters of the power distribution system and are constants. Under the condition of normal operation, the comprehensive optimization device only outputs the positive sequence voltage e⁺And e is a⁺Is close to the ac rated voltage of the distribution network, so that at the instant of a ground fault, e⁺Can be considered approximately as a constant. From I_fIt can be seen that in determining R₀Under the premise of (1), when the fault is detected, the ground resistance R_fWhen equal to 0, I_fA maximum value will be obtained. Fault current I_fConstrained by factors such as system overcurrent and the like, the maximum short-circuit current is set to be I_f0。

Thus, for the ith (1 ≦ I ≦ n) fault point, at maximum short circuit current I_f0Under the limitation of (3), R can be obtained₀Lower limit value of

SelectingThe highest value being the direct resistance R₀Lower limit value R of_min。

In the fifth step, similar to the calculation process in the third step, the complex sequence network equation according to the formulas (20) and (21) is combined with the f provided in the step 2_sEquivalent model under frequency, can be calculated to obtain f_sFrequency of flowing through fault pointIs f_sCurrent of (I)_fsAnd a direct current resistance R₀The relation between them.

Wherein,it can be seen that k_s6And are constants related to the power distribution network structure and parameters.

In the sixth step, as can be seen from formula (25), exceptR_fAnd R₀The three variables and the rest parameters are determined by the grid structure and the parameters of the power distribution system and are constants. After a fault, the comprehensive optimization device has the injection frequency f_sThe voltage and current signals of (2) cause most of the signals to flow through fault points, thereby being matched with the traditional line selection method to improve the line selection accuracy. The injected voltage signal is used for ensuring that the power distribution system does not generate resonance, overvoltage and the likeIt should not be too large, and the amplitude is generally set to be less than 10% of the rated voltage of the fundamental frequency.

To enable a faulty line to be monitored effectively_sFrequency signal of alternating current, I_fsShould be greater than the minimum current I that can be considered as a valid signal_fs0. Determination of good I_fsMinimum sum ofCan obtain (3R)_f+3k_s5R₀) Is measured. I is_fsIs easily influenced by the shunt resistance of the feeder line to the ground, and if the parameter of the ground capacitance of a certain cable feeder line is 0.27 mu F/km and the length of the cable is 10km, the frequency F is_sLower capacitive reactance to groundIs 268 omega. To ensure the accuracy of line selection, a fault ground resistor R_fMust not be larger than 268 omega, otherwise, the line selection error is caused. Thus, R_fShould be less than a certain resistance R_f0Such as 100 omega. When the grounding resistance exceeds R_f0In time, the invention should cooperate with other existing line selection methods to select lines, so as to ensure the accuracy of line selection. After R is determined_fThen, the ith fault point, R, can be obtained₀Upper limit value of

SelectingThe smallest value being the direct resistance R₀Upper limit value R of_max。

In the seventh step, R calculated in the fourth step_minAnd R calculated in the sixth step_maxR may exist due to different parameters related to the two_min>R_maxThe case (1). If R is_max≥R_minThen the direct current resistance R₀May be in { R_min，R_maxSelecting within the range; depending on further requirements of fault current control and line selection accuracy, a bias towards R may be selected_maxOr R_min。

If R is_max<R_minThen in the sixth step by decreasing R_f0Calculation of R_maxParameter until R is satisfied_max≥R_minUnder the condition of (1) R₀Is set as R_min(R_max) And record the corresponding R_f0. At this time, the meaning containedThe thinking is that: in the R₀If the grounding resistance is less than the corresponding R_f0Otherwise, other existing line selection methods are required to participate in line selection calculation together so as to ensure the line selection accuracy.

Example 2

The embodiment provides a direct current resistance selection system of a complex power distribution network comprehensive optimization device. The complex power distribution network comprehensive optimization device is a transformer-free hybrid MMC, the alternating current side of the hybrid MMC is directly connected with a bus of a transformer substation through an alternating current breaker, and a connecting transformer is not arranged in the middle of the hybrid MMC; positive pole of DC side and capacitor C₁Connected with the negative electrode of the DC side and a capacitor C₂Connected to a capacitor C₁Another terminal of (1) and a capacitor C₂Is connected to the other end of the resistor and is simultaneously connected to a direct current resistor R₀Connected, DC resistance R₀And the other end of the same is directly grounded. Each bridge arm of the hybrid MMC is formed by cascading a plurality of submodules, the bridge arm reactors are connected in series, the number ratio of the submodules in the bridge arms is 1:1, and the driving circuit board of each submodule is powered by the capacitor voltage of the corresponding submodule.

The direct current resistance selection system comprises:

equivalent circuit first construction unit: positive sequence, negative sequence and zero sequence three-sequence base frequency equivalent circuit and sampling frequency f for constructing complex power distribution network comprehensive optimization device_sThe equivalent circuit is formed by connecting an equivalent voltage source and an equivalent impedance in series;

the equivalent circuit second construction unit: selecting n typical single-phase earth fault points, and constructing the fundamental frequency and the sampling frequency f of the power distribution system at the fault points_sA lower positive sequence, negative sequence and zero sequence equivalent circuit;

a first relational expression calculation unit: setting different fault ground resistances R_fCalculating according to the positive sequence, negative sequence and zero sequence base frequency equivalent circuit at the fault pointTo fault current I_fAnd a direct current resistance R₀The relation between;

a direct current resistance lower limit value determination unit: based on maximum fault current not exceeding maximum short-circuit current I_f0Determining a lower limit value R of the direct current resistance_min；

A second relational expression calculation unit: according to sampling frequency f at fault point_sCalculating a positive sequence, a negative sequence and a zero sequence equivalent circuit to obtain a fault point sampling frequency f_sCurrent of (I)_fsAnd a direct current resistance R₀The relation between;

a direct current resistance upper limit value determination unit: based on fault grounding resistance being smaller than set resistance R_f0And the frequency of the inflow fault point is f_sIs not less than the minimum current I of the effective signal_fs0Determining an upper limit value R of the direct current resistance_max；

A direct current resistance obtaining unit: according to R_min、R_maxAnd the relation between the two to obtain the direct current resistance R₀。

It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (10)

1. A direct current resistance selection method of a complex power distribution network comprehensive optimization device is characterized in that the complex power distribution network comprehensive optimization device is a transformer-free hybrid MMC, the alternating current side of the hybrid MMC is directly connected with a substation bus through an alternating current breaker, and a connection transformer is not arranged in the middle of the hybrid MMC; positive pole of DC side and capacitor C₁Connected with the negative electrode of the DC side and a capacitor C₂Connected to a capacitor C₁Another terminal of (1) and a capacitor C₂Is connected to the other end of the resistor and is simultaneously connected to a direct current resistor R₀Connected, DC resistance R₀The other end of the first and second electrodes is directly grounded;it is characterized in that the preparation method is characterized in that,

the direct current resistance selection method comprises the following steps:

1) positive sequence, negative sequence and zero sequence three-sequence base frequency equivalent circuit and sampling frequency f for constructing complex power distribution network comprehensive optimization device_sThe equivalent circuit is formed by connecting an equivalent voltage source and an equivalent impedance in series;

2) selecting n typical single-phase earth fault points, and constructing the fundamental frequency and the sampling frequency f of the power distribution system at the fault points_sA lower positive sequence, negative sequence and zero sequence equivalent circuit;

3) setting different fault ground resistances R_fCalculating to obtain fault current I according to the positive sequence, negative sequence and zero sequence base frequency equivalent circuit at the fault point_fAnd a direct current resistance R₀The relation between;

4) based on maximum fault current not exceeding maximum short-circuit current I_f0Determining a lower limit value R of the direct current resistance_min；

5) According to sampling frequency f at fault point_sCalculating a positive sequence, a negative sequence and a zero sequence equivalent circuit to obtain a fault point sampling frequency f_sCurrent of (I)_fsAnd a direct current resistance R₀The relation between;

6) based on fault grounding resistance being smaller than set resistance R_f0And the frequency of the inflow fault point is f_sIs not less than the minimum current I of the effective signal_fs0Determining an upper limit value R of the direct current resistance_max；

7) R obtained according to step 4)_minR obtained in step 6)_maxAnd the relation between the two to obtain the direct current resistance R₀。

2. The method for selecting direct current resistance according to claim 1, wherein, in the step 1),

the positive sequence fundamental frequency equivalent voltage source is e⁺Positive sequence fundamental frequency equivalent impedance of Z⁺(ii) a The equivalent voltage source of the negative sequence fundamental frequency is 0, and the equivalent impedance of the negative sequence fundamental frequency is Z^-(ii) a The zero-sequence fundamental frequency equivalent voltage source is 0, and the zero-sequence fundamental frequency equivalent impedanceIs Z⁰(ii) a Wherein,ω₀＝2πf₀，f₀50 Hz; j represents the imaginary unit; r and L are equivalent resistance and inductance of a bridge arm respectively; r₀Is a direct current resistance; c_dIs a capacitor C₁And C₂The capacitance value of (a); e.g. of the type⁺The positive-sequence fundamental frequency voltage output by the MMC is obtained by the MMC according to the control of a power distribution system;

positive sequence f_sFrequency equivalent voltage source of 0, positive sequence f_sFrequency equivalent impedance ofNegative sequence f_sFrequency equivalent voltage source of 0, negative sequence f_sFrequency equivalent impedance ofZero sequence f_sA frequency equivalent voltage source ofZero sequence f_sFrequency equivalent impedance ofWherein,ω_s＝2πf_s，f_s＝220Hz；frequency of output for MMC_sThe zero sequence voltage of (2) is obtained by controlling the MMC according to the power distribution system.

3. The method for selecting direct current resistance according to claim 2, wherein, in the step 2),

positive sequence fundamental frequency equivalence at fault pointsVoltage source k₁₁E_s+k₁₂e⁺Positive sequence fundamental frequency equivalent impedance is k₁₃+k₁₄Z⁺(ii) a The negative sequence fundamental frequency equivalent voltage source is 0, and the positive sequence fundamental frequency equivalent impedance is k₁₃+k₁₄Z^-(ii) a The zero-sequence fundamental frequency equivalent voltage source is 0, and the zero-sequence fundamental frequency equivalent impedance is k₁₅+k₁₆Z⁰(ii) a Wherein Es is the power supply voltage of the power distribution network, k₁₁、k₁₂、k₁₃、k₁₄、k₁₅、k₁₆The fault location is determined by the structure and parameters of the power distribution network and is constant for the specified fault location;

positive sequence f at fault point_sFrequency equivalent voltage source of 0, positive sequence f_sFrequency equivalent impedance ofNegative sequence f_sFrequency equivalent voltage source of 0, negative sequence f_sFrequency equivalent impedance ofZero sequence f_sA frequency equivalent voltage source ofZero sequence f_sFrequency equivalent impedance ofk_s1、k_s2、k_s3、k_s4、k_s5It is a constant for a given fault location, determined by the distribution network structure and parameters.

4. The method of claim 3, wherein in step 3), the fault current I is selected_fAnd a direct current resistance R₀The relationship between them is as follows:

<mrow> <msub> <mi>I</mi> <mi>f</mi> </msub> <mo>=</mo> <mfrac> <mrow> <mn>3</mn> <mrow> <mo>(</mo> <msub> <mi>k</mi> <mn>11</mn> </msub> <msub> <mi>E</mi> <mi>s</mi> </msub> <mo>+</mo> <msub> <mi>k</mi> <mn>12</mn> </msub> <msup> <mi>e</mi> <mo>+</mo> </msup> <mo>)</mo> </mrow> </mrow> <mrow> <msub> <mi>k</mi> <mn>17</mn> </msub> <mo>+</mo> <mn>3</mn> <msub> <mi>R</mi> <mi>f</mi> </msub> <mo>+</mo> <mn>3</mn> <msub> <mi>k</mi> <mn>16</mn> </msub> <msub> <mi>R</mi> <mn>0</mn> </msub> </mrow> </mfrac> <mo>,</mo> </mrow>

wherein,k₁₇and are constants related to the power distribution network structure and parameters.

5. The method for selecting DC resistance according to claim 4, wherein, in the step 4),

for the ith fault point, I is more than or equal to 1 and less than or equal to n, and the maximum short-circuit current I is_f0Under the limitation of (3), obtaining a direct current resistance R₀Lower limit value ofWherein I_f0Taking out the mixture of 30A and 30B,

<mrow> <msubsup> <mi>R</mi> <mi>min</mi> <mi>i</mi> </msubsup> <mo>=</mo> <mfrac> <mrow> <mn>3</mn> <mrow> <mo>(</mo> <msub> <mi>k</mi> <mn>11</mn> </msub> <msub> <mi>E</mi> <mi>s</mi> </msub> <mo>+</mo> <msub> <mi>k</mi> <mn>12</mn> </msub> <msup> <mi>e</mi> <mo>+</mo> </msup> <mo>)</mo> </mrow> </mrow> <mrow> <mn>3</mn> <msub> <mi>k</mi> <mn>16</mn> </msub> <msub> <mi>I</mi> <mrow> <mi>f</mi> <mn>0</mn> </mrow> </msub> </mrow> </mfrac> <mo>-</mo> <mfrac> <msub> <mi>k</mi> <mn>17</mn> </msub> <mrow> <mn>3</mn> <msub> <mi>k</mi> <mn>16</mn> </msub> </mrow> </mfrac> <mo>,</mo> </mrow>

selectingThe medium maximum value is the direct current resistance R₀Lower limit value R of_min，

<mrow> <msub> <mi>R</mi> <mi>min</mi> </msub> <mo>=</mo> <mi>m</mi> <mi>a</mi> <mi>x</mi> <mo>{</mo> <msubsup> <mi>R</mi> <mi>min</mi> <mn>1</mn> </msubsup> <mo>,</mo> <msubsup> <mi>R</mi> <mi>min</mi> <mn>2</mn> </msubsup> <mo>,</mo> <mo>...</mo> <mo>,</mo> <msubsup> <mi>R</mi> <mi>min</mi> <mi>n</mi> </msubsup> <mo>}</mo> <mo>.</mo> </mrow>

6. The method for selecting DC resistance according to claim 5, wherein in step 5), the current I_fsAnd a direct current resistance R₀The relationship between them is as follows:

<mrow> <msub> <mi>I</mi> <mrow> <mi>f</mi> <mi>s</mi> </mrow> </msub> <mo>=</mo> <mfrac> <mrow> <mn>3</mn> <msub> <mi>k</mi> <mrow> <mi>s</mi> <mn>3</mn> </mrow> </msub> <msubsup> <mi>e</mi> <mi>s</mi> <mn>0</mn> </msubsup> </mrow> <mrow> <msub> <mi>k</mi> <mrow> <mi>s</mi> <mn>6</mn> </mrow> </msub> <mo>+</mo> <mn>3</mn> <msub> <mi>R</mi> <mi>f</mi> </msub> <mo>+</mo> <mn>3</mn> <msub> <mi>k</mi> <mrow> <mi>s</mi> <mn>5</mn> </mrow> </msub> <msub> <mi>R</mi> <mn>0</mn> </msub> </mrow> </mfrac> <mo>,</mo> </mrow>

wherein,k_s6and are constants related to the power distribution network structure and parameters.

7. The method for selecting direct current resistance according to claim 6, wherein, in step 6),

ith fault point, R₀Upper limit value ofComprises the following steps:

<mrow> <msubsup> <mi>R</mi> <mrow> <mi>m</mi> <mi>a</mi> <mi>x</mi> </mrow> <mi>i</mi> </msubsup> <mo>=</mo> <mfrac> <mrow> <mn>3</mn> <msub> <mi>k</mi> <mrow> <mi>s</mi> <mn>3</mn> </mrow> </msub> <msubsup> <mi>e</mi> <mi>s</mi> <mn>0</mn> </msubsup> </mrow> <mrow> <mn>3</mn> <msub> <mi>k</mi> <mrow> <mi>s</mi> <mn>5</mn> </mrow> </msub> <msub> <mi>I</mi> <mrow> <mi>f</mi> <mi>s</mi> <mn>0</mn> </mrow> </msub> </mrow> </mfrac> <mo>-</mo> <mfrac> <mrow> <msub> <mi>k</mi> <mrow> <mi>s</mi> <mn>6</mn> </mrow> </msub> <mo>+</mo> <mn>3</mn> <msub> <mi>R</mi> <mrow> <mi>f</mi> <mn>0</mn> </mrow> </msub> </mrow> <mrow> <mn>3</mn> <msub> <mi>k</mi> <mrow> <mi>s</mi> <mn>5</mn> </mrow> </msub> </mrow> </mfrac> <mo>,</mo> </mrow>

wherein,set to less than 10% of the rated voltage of the fundamental frequency; r_f0Take 100 Ω, I_fs0Taking 1A; selectingThe minimum value is the DC resistance R₀Upper limit value R of_max，

<mrow> <msub> <mi>R</mi> <mi>max</mi> </msub> <mo>=</mo> <mi>min</mi> <mo>{</mo> <msubsup> <mi>R</mi> <mi>max</mi> <mn>1</mn> </msubsup> <mo>,</mo> <msubsup> <mi>R</mi> <mi>max</mi> <mn>2</mn> </msubsup> <mo>,</mo> <mo>...</mo> <mo>,</mo> <msubsup> <mi>R</mi> <mi>max</mi> <mi>n</mi> </msubsup> <mo>}</mo> <mo>.</mo> </mrow>

8. The method for selecting direct current resistance according to claim 7, wherein, in step 7),

if R is_max≥R_minThen the direct current resistance R₀In { R_min，R_maxSelecting within the range; the selection bias is R based on the further requirements of fault current control and line selection accuracy_maxOr R_min；

If R is_max<R_minThen in step 6) by decreasing R_f0Calculation of R_maxParameter until R is satisfied_max≥R_minUnder the condition of (1) R₀Is set as R_minOr R_maxAnd recording the corresponding R_f0。

9. The method according to claim 1, wherein the DC resistance is selected from the group consisting of,

each bridge arm of the hybrid MMC is formed by cascading a plurality of submodules, the bridge arm reactors are connected in series, the number ratio of the submodules in the bridge arms is 1:1, and the driving circuit board of each submodule is powered by the capacitor voltage of the corresponding submodule.

10. A direct current resistance selection system of a complex power distribution network comprehensive optimization device is disclosed, wherein the complex power distribution network comprehensive optimization device is a mixed MMC without a transformer; the direct current resistance selection system is characterized by comprising:

equivalent circuit first construction unit: positive sequence, negative sequence and zero sequence three-sequence base frequency equivalent circuit and sampling frequency f for constructing complex power distribution network comprehensive optimization device_sEquivalent circuit of the following, etcThe value circuit is formed by connecting an equivalent voltage source and an equivalent impedance in series;

the equivalent circuit second construction unit: selecting n typical single-phase earth fault points, and constructing the fundamental frequency and the sampling frequency f of the power distribution system at the fault points_sA lower positive sequence, negative sequence and zero sequence equivalent circuit;

a first relational expression calculation unit: setting different fault ground resistances R_fCalculating to obtain fault current I according to the positive sequence, negative sequence and zero sequence base frequency equivalent circuit at the fault point_fAnd a direct current resistance R₀The relation between;

a direct current resistance lower limit value determination unit: based on maximum fault current not exceeding maximum short-circuit current I_f0Determining a lower limit value R of the direct current resistance_min；

A second relational expression calculation unit: according to sampling frequency f at fault point_sCalculating a positive sequence, a negative sequence and a zero sequence equivalent circuit to obtain a fault point sampling frequency f_sCurrent of (I)_fsAnd a direct current resistance R₀The relation between;

a direct current resistance upper limit value determination unit: based on fault grounding resistance being smaller than set resistance R_f0And the frequency of the inflow fault point is f_sIs not less than the minimum current I of the effective signal_fs0Determining an upper limit value R of the direct current resistance_max；

A direct current resistance obtaining unit: according to R_min、R_maxAnd the relation between the two to obtain the direct current resistance R₀。