CN111814305A - Single-phase NPC type H-bridge cascaded inverter capacitor voltage unevenness modeling method based on pulse jump SVPWM - Google Patents

Abstract

The invention discloses a pulse-hopping SVPWM-based single-phase NPC type H-bridge cascaded inverter capacitor voltage unevenness modeling method, wherein a capacitor voltage unevenness mechanism analyzes equivalent circuits when different vectors act, influences of capacitor voltage unevenness including capacitor size, switching frequency, modulation ratio, load impedance and power factor are determined, a capacitor voltage unevenness current expression is obtained, a method of combining component superposition and a two-port equivalent circuit is adopted, a capacitor voltage unevenness first order ordinary differential equation model is built from angles of a capacitor voltage unevenness switching function and capacitor voltage unevenness current, and unknown parameters of the model are solved by combining actual working conditions of an inverter. The established multi-factor mathematical model for the uneven capacitor voltage is used for uniformly modeling the capacitance value, the switching frequency, the modulation ratio, the load impedance, the power factor and other factors of the capacitor, so that a six-dimensional spatial model for the uneven capacitor voltage is established, and the uneven change condition of the capacitor voltage when a plurality of variables act simultaneously can be analyzed.

Description

Single-phase NPC type H-bridge cascaded inverter capacitor voltage unevenness modeling method based on pulse jump SVPWM

Technical Field

The invention belongs to the technical field of power electronics, and particularly relates to a modeling method for voltage unevenness of a capacitor of a single-phase NPC type H-bridge cascaded inverter based on pulse-hopping SVPWM.

Background

In recent years, with the development of power electronics technology, single-phase multi-level inverters have been widely used in various applications. The single-phase CHB-NPC inverter has the advantages of low output voltage harmonic content, high output power, low electromagnetic interference and the like, and has obvious application advantages in the fields of rail transit, electromagnetic emission, new energy power generation and the like.

The dc side capacitor voltage non-uniformity is an inherent problem of single phase CHB-NPC inverters, which can lead to poor inverter output voltage quality. More researches mainly realize that the voltage-sharing effect of the direct-current side capacitor is controlled by optimizing a modulation algorithm, and although a better voltage-sharing effect is obtained, quantitative analysis of various influencing factors on the unevenness of the capacitor voltage is lacked, the influence of the characteristic of the parameters of the inverter on the unevenness of the capacitor voltage is ignored, and the reduction of the unevenness of the voltage is not deeply researched from the design link of the inverter, so that the voltage-sharing effect is limited by the condition of the inverter.

In the research of a capacitor voltage balance domain of a diode-clamped five-level inverter (reported in the electrotechnical science), leap et al obtains the capacitor voltage balance domain in a space vector diagram by solving the influence of each vector action on branch bus current. However, the capacitor voltage unevenness is not quantitatively modeled in the analysis process, and the vector balance domain analysis method is not suitable for the single-phase CHB-NPC inverter. Liu war et al obtained a balanced domain curve of a midpoint potential with respect to a modulation ratio and a power factor by establishing a capacitance voltage unevenness formula in a research on a neutral point voltage balance problem of an active midpoint clamping type five-level inverter bus based on a space voltage vector (reported in Chinese Motor engineering), but lacked a modeling research on a voltage unevenness mechanism. In the three-level NPC inverter capacitance-voltage balance control analysis based on the midpoint current (reported in Chinese Motor engineering), Chenzhong et al analyzes the voltage-sharing balance characteristics of a three-phase NPC inverter, provides balance domains of power factors and modulation ratios in different modulation ranges, but does not establish a capacitance-voltage unified model influenced by multiple factors. Li Yong et al analyzed the midpoint potential non-uniformity mechanism of a T-type three-level inverter in the midpoint balance modeling and control of the T-type three-level inverter (power engineering technology), established a capacitance-voltage non-uniformity transfer function model, and analyzed the influence of current and power factors on the capacitor voltage non-uniformity, but did not further study the influence degree of other factors such as switching frequency.

The technology does not establish a mathematical model of capacitor voltage unevenness with uniform multi-factors such as capacitor size, switching frequency, power factor, modulation ratio, load impedance and the like, cannot analyze the influence of the multi-factors on the capacitor voltage unevenness simultaneously, and cannot further obtain key factors influencing the capacitor voltage unevenness when the inverter works under different working conditions. Although the specific value of the uneven capacitor voltage can be determined through software simulation, the obtained uneven capacitor voltage value is only a group of data points of the inverter running under a specific working condition, the action degree of each influence factor on the uneven capacitor voltage cannot be theoretically explained, the overall change rule of the uneven capacitor voltage cannot be analyzed, and theoretical guidance cannot be provided for parameter design of the inverter.

Disclosure of Invention

The invention aims to provide a single-phase NPC type H-bridge cascaded inverter capacitor voltage unevenness modeling method based on pulse jump SVPWM, wherein multiple variables act simultaneously, and the modeling method is high in precision.

In order to achieve the purpose, the modeling method for the capacitance-voltage unevenness of the single-phase NPC type H-bridge cascaded inverter based on pulse-hopping SVPWM (space vector pulse width modulation) is designed, a topological structure of the single-phase CHB-NPC inverter is formed by four NPC half-bridge circuits, two NPC half-bridges are connected in parallel to form a five-level NPC type H-bridge, the two H-bridges are cascaded, the upper H-bridge is a cascaded unit CH1, the lower H-bridge is a cascaded unit CH2, the cascaded unit CH1 is formed by a bridge arm a and a bridge arm b, the cascaded unit CH2 is formed by a bridge arm c and a bridge arm d_xRepresents the x-th bridge arm state, x ═ a, b, c, d; the method is characterized in that: the capacitor voltage unevenness modeling method comprises the following steps:

1) the capacitor voltage unevenness mechanism analyzes equivalent circuits when different vectors act, influences of the capacitor voltage unevenness are determined to include capacitance size, switching frequency, modulation ratio, load impedance and power factor, and the expression of the capacitor voltage unevenness is as follows:

and obtaining the current expression of the capacitor voltage unevenness to cause the voltage unevenness Delta U of the upper H bridge_h1Current i of_c1The expression is as follows:

delta U causing lower H bridge voltage non-uniformity_h2Current i of_c2The expression is as follows:

where k denotes the kth vector contribution, i_LkRepresents the load current, S, at the time of the k-th vector action_akRepresents the state of the bridge arm a at the time of the k-th vector, S_bkRepresents the state of the bridge arm b at the time of the kth vector, S_ckRepresents the state of the bridge arm c at the time of the kth vector, S_dkRepresenting the state of a bridge arm d at the k vector;

2) the method of combining component superposition and two-port equivalent circuit is adopted, a first-order ordinary differential equation model of capacitor voltage unevenness is established from the angles of capacitor voltage unevenness switching function and capacitor voltage unevenness current, and unknown parameters of the model are solved by combining the actual working condition of the inverter

Capacitor voltage unevenness first order differential equation mathematical model formula (31)

Wherein, U_HIs a constant voltage source voltage at the DC side of the H bridge, U_d1(t_m) The/2 is the uneven peak value of the capacitor voltage in one fundamental wave period, C is the capacitance value of the supporting capacitor, | Z | is the load impedance of the inverter,

as the load power factor angle, omega_rFor modulating the fundamental angular frequency of the wave, m is the modulation ratio, f_sIs the switching frequency. The unknown parameter comprises S_txFundamental angular frequency omega_s1、S_txAngle of power factor

Power factor angle coefficient k₁Indefinite term t of median theorem, indefiniteIntegral term r and peak time t_m；

After the solution is completed, the parameter S is added_txFundamental angular frequency omega_s1、S_txAngle of power factor

Power factor angle coefficient k₁Median theorem indefinite term t, indefinite integral term r and peak time t_mAnd (31) the mathematical modeling of the capacitor voltage unevenness of the single-phase CHB-NPC inverter is completed.

Further, in the step 2), the mathematical model of the first-order differential equation of the capacitor voltage unevenness is approximated by a time scale reduction method, the switching function of the capacitor voltage unevenness is sinusoidal, and the coupling condition is decoupled.

Further, after mathematical modeling of the capacitor voltage unevenness of the single-phase CHB-NPC inverter in the step 2), sensitivity of the capacitor voltage unevenness is analyzed, and factors affecting the capacitor voltage unevenness are sorted, wherein the factors affecting the capacitor voltage unevenness include capacitor size, switching frequency, modulation ratio, load impedance and power factor.

Compared with the prior art, the invention has the following advantages:

1) the multi-factor mathematical model for the uneven capacitor voltage is established, the factors such as the capacitance value of the capacitor, the switching frequency, the modulation ratio, the load impedance, the power factor and the like are modeled uniformly, the six-dimensional spatial model for the uneven capacitor voltage is established, and the uneven change condition of the capacitor voltage when a plurality of variables act simultaneously can be analyzed.

2) The invention establishes a mathematical model of the uneven voltage of the capacitor, and performs mathematical modeling by adopting a method of combining component superposition and a two-port equivalent circuit, so that the obtained mathematical model of the uneven voltage of the capacitor has high precision. And carrying out sensitivity analysis on the influence factors of the capacitor voltage unevenness in the model so as to pertinently guide the parameter design of the inverter.

Drawings

FIG. 1 is a single phase CHB-NPC inverter topology;

FIG. 2 is a circuit diagram showing the equivalent effect of the switching vector (0,0,0,0) of level 0;

FIG. 3 is a circuit diagram showing the equivalent effect of the switching vector (1, -1,1, -1) of +4E level;

FIG. 4 is a circuit diagram showing the equivalent effect of the switching vector (-1,1, -1,1) at level-4E;

FIG. 5 is a two-port equivalent circuit of a single-phase CHB-NPC inverter;

FIG. 6 shows the time t of uneven peak of capacitor voltage_mS in neighborhood_txA value law graph of (1);

FIG. 7 is U_d1max>0 time S_txA value map of (1);

FIG. 8 is U_d1max< 0 time S_txA value map of (1);

FIG. 9 is a power factor angle

And

the relationship between;

FIGS. 10 to 14 are graphs comparing the model simulation results with the theoretical calculation results;

FIGS. 15 to 19 are the comparison of the experimental results with the theoretical calculation results.

Detailed Description

The invention is described in further detail below with reference to the figures and the specific embodiments.

The modeling method for the capacitor voltage unevenness of the single-phase NPC type H-bridge cascaded inverter based on pulse jump SVPWM comprises three parts, namely capacitor voltage unevenness mechanism analysis, capacitor voltage unevenness mathematical modeling and solving, capacitor voltage unevenness sensitivity analysis and the like. The relationship among the three is as follows: the capacitor voltage unevenness mechanism analyzes equivalent circuits when different vectors act, and the influence factors of capacitor voltage unevenness are determined as follows: the current expression influencing the uneven voltage of the capacitor is obtained according to the capacitance size, the switching frequency, the power factor, the load impedance and the modulation ratio. The capacitor voltage unevenness modeling and solving unifies five factors influencing the capacitor voltage unevenness, modeling is carried out by utilizing a capacitor voltage unevenness current expression, and finally a first-order ordinary differential equation model of the capacitor voltage unevenness is obtained. And analyzing the sensitivity of the capacitor voltage unevenness to obtain the sequencing of the influence degree of the capacitor voltage unevenness, so as to give important consideration to main factors during the design of inverter parameters. The specific functions of each part are as follows:

the capacitive voltage unevenness mechanism analysis is used for analyzing influence factors of capacitive voltage unevenness and determining main influence factors of capacitive voltage unevenness, and comprises the following steps: modulation ratio, power factor, capacitance size, switching frequency, load impedance, and a current expression of capacitance-to-voltage non-uniformity is established.

And modeling and solving the capacitor voltage unevenness, and establishing a quantitative relation between factors such as a capacitor capacitance value, a switching frequency, a modulation ratio, load impedance, a power factor and the like and the capacitor voltage unevenness. The method combines component superposition and two-port equivalent circuits to perform mathematical modeling, and establishes a mathematical relation between a capacitor voltage non-uniform switching function and capacitor voltage non-uniform by analyzing the effect of the capacitor voltage non-uniform current.

And analyzing the sensitivity of the uneven voltage of the capacitor, sequencing the action sizes of the factors influencing the uneven voltage of the capacitor, and specifically inhibiting the main factors during the design of the inverter parameters.

The capacitive voltage unevenness mechanism analysis confirms the influence factors of the capacitive voltage unevenness and the current expression causing the capacitive voltage unevenness; the modeling and solving of the capacitor voltage unevenness carry out integral operation on a capacitor voltage unevenness current expression, and influence factors such as a capacitor capacitance value, a switching frequency, a modulation ratio, load impedance, a power factor and the like are unified into a capacitor voltage unevenness mathematical model. And (4) analyzing the sensitivity of the uneven voltage of the capacitor, and sorting various factors influencing the uneven voltage of the capacitor.

The single-phase CHB-NPC inverter topology structure shown in figure 1 is composed of four NPC half-bridge circuits, two NPC half-bridges are connected in parallel to form a five-level NPC type H-bridge, and then the two H-bridges are cascaded to obtain the single-phase CHB-NPC inverter. Each H bridge DC side is provided with two supporting capacitors which are sequentially C from top to bottom₁,C₂,C₃,C₄，C₁,C₂,C₃,C₄Corresponding voltage values are respectively U_C1,U_C2,U_C3,U_C4The direct current end is composed of two independent sources U with equal size_H1And U_H2And power is supplied, and the output is connected with an RL load. The single-phase CHB-NPC inverter can output nine levels: 4E, ± 3E, ± 2E, ± E and 0. The single-phase CHB-NPC inverter is defined as follows:

a cascade unit: the upper H bridge is a cascade unit CH1, and the lower H bridge is a cascade unit CH 2.

Bridge arm definition: the cascade unit CH1 is composed of a bridge arm a and a bridge arm b, the cascade unit CH2 is composed of a bridge arm c and a bridge arm d, the bridge arms connected with the load are the bridge arm a and the bridge arm d, and S_xRepresents the x-th bridge arm state, x ═ a, b, c, and d.

Defining a switch: bridge arm S_xThe four switches are S from top to bottom_xiX is a, b, c, d, i is 1,2,3,4, switch S_xiThe pilot is denoted by 1 and off is denoted by 0.

Bridge arm state: each bridge arm S_xThree states, 1,0, -1, can be represented as:

the current direction: the direction in which the current flows out of the inverter is defined as a positive direction.

The modeling method for the uneven capacitor voltage specifically comprises the following steps:

2) analysis of capacitor voltage non-uniformity mechanism

The capacitor voltage unevenness mechanism analyzes equivalent circuits when different vectors act, and the influence factors of capacitor voltage unevenness are determined as follows: the capacitance, the switching frequency, the modulation ratio, the load impedance and the power factor are used for obtaining a capacitance voltage uneven current expression;

2.1) capacitor Voltage non-uniformity accumulation characteristic

Setting the capacitance C in the Kth switching period₁,C₂,C₃,C₄Respectively has a voltage change amount of delta U_Ci(K) 1,2,3,4, the capacitance voltage expression at the end of K switching cycles is:

U_Ci(K)＝U_Ci(K-1)+ΔU_Ci(K) (2)

in the formula of U_Ci(K-1) and U_Ci(K) Respectively representing the capacitances C at the end of the K-th and Kth switching cycles_iThe voltage value of (2). The capacitor voltage of CH1 is analyzed to define the capacitor voltage unevenness DeltaU of the upper H bridge at the end of the Kth switching period_h1(K) The expression is as follows:

combining formulas (2) and (3) to obtain the capacitance voltage unevenness Delta U of the upper H bridge_h1(K) The expression is as follows:

iterative calculation is carried out on the first K switching periods of the formula (4) to obtain the capacitor voltage unevenness of 0-KT_sReal-time expression of capacitor voltage unevenness in time period:

the above equation shows that the capacitor voltage is not uniform by DeltaU when the nth switching period is over_h1(n) is the accumulation of the capacitor voltage non-uniformities for the first n switching cycles. If considered from the continuous time domain perspective, Δ U_h1The expression is an integral function with variable upper limit, and the uneven capacitor voltage has an accumulation characteristic.

2.2) equivalent Circuit analysis

The four power switches of each phase of the single-phase CHB-NPC inverter are simplified into single-pole three-throw switches, and C is assumed₁＝C₂＝C₃＝C₄The pulse-skipping SVPWM modulation algorithm has 27 action vectors, and the switching vectors of 0 and ± 4E levels are only used as an example for explanation.

Equivalent circuit of 0 level vector (0,0,0,0) action as shown in fig. 2, switch S_a2,S_b2,S_c2,S_d2And (5) closing. No current flows through the capacitor C₁,C₂,C₃,C₄Vector of(0,0,0,0) does not charge or discharge the DC side capacitor, and has no influence on the voltage unevenness of the capacitor.

The equivalent circuit of the action of the switching vector (1, -1,1, -1) of +4E level is shown in FIG. 3, the switch S_a1,S_b1,S_c1,S_d1And (5) closing. When current i_L>At 0, the bus capacitors of CH1 and CH2 are discharged simultaneously; when current i_L<At 0, the bus capacitors of CH1 and CH2 are charged simultaneously, and the variation of the capacitor voltage is:

wherein Δ t represents the action time of the vector (1, -1,1, -1). The equivalent circuit of the switching vector (-1,1, -1,1) of level-4E is shown in FIG. 4. Switch S_a3,S_b1,S_c3,S_d1Closed when load current i_L>At 0, the bus capacitors of CH1 and CH2 are discharged simultaneously, and the current i_L<When 0, the upper and lower H bridge bus capacitance charges simultaneously, and the capacitance voltage variation is:

it can be seen that the 4E level will only be for C₁,C₂,C₃,C₄The capacitor is charged or discharged at the same time, and the charge quantity of the charge and the discharge is completely equal, so that the capacitor voltage unevenness of the CH1 and the CH2 is not influenced.

The remaining 24 switching vector equivalent circuits were analyzed, and the relationship between the switching vector and the change in the capacitance voltage was obtained as shown in table 1. Wherein "-1", "+ 1", and "0" in the action vector column indicate the arm state defined by the formula (1), and "-1" in the capacitance-voltage change column indicates that the change amount of the capacitance voltage is-i_LΔ t/C, "+ 1" indicates a change in capacitance voltage of i_LΔ t/C, "0" indicates that the capacitor voltage does not change.

TABLE 1 correspondence between action vector and capacitance voltage variation

Suppose S_v＝S_a-S_b+S_c-S_dAccording to table 1, the following functional relationship exists between the switching vector and the incremental capacitance voltage relationship:

when S_vWhen the voltage is more than or equal to 0, the relation between the switching vector and the increment of the capacitor voltage is as follows:

when S_vWhen the voltage is less than 0, the relation between the switching vector and the increment of the capacitor voltage is as follows:

the expressions of the capacitance voltage unevenness obtained by the vertical connection type (3), (8) and (9) are as follows:

where the subscript k denotes the kth vector contribution, Δ U_h1Indicates the voltage of upper H-bridge capacitor is not uniform, delta U_h2Indicates the voltage of the lower H-bridge capacitor is not uniform, i_LkRepresents the load current,. DELTA.t, at the time of the k-th vector action_kRepresenting the action time of the kth vector, a sign (x) sign function being defined as

Combined (10) to cause upper H-bridge voltage non-uniformity DeltaU_h1Current i of_c1The expression is as follows:

delta U causing lower H bridge voltage non-uniformity_h2Current i of_c2The expression is as follows:

introducing a switching frequency f_sAnd load impedance Z to Deltat_kAnd i_LkExpressed, the formula (10) is:

wherein d is_kRepresents the kth vector duty cycle, u_okRepresents the output voltage of the inverter when the kth vector acts, represents the magnitude of impedance,

representing the power factor angle. The formula (11) shows that S is_ak+S_bkE {1,0, -1} and S_ck+S_dkE {1,0, -1}, the magnitude of the k-th period capacitor voltage imbalance is represented by C, f_s,|Z|,

And u_oDetermining that the direction of change is S_a+S_b,S_c+S_d,S_vAnd u_oAnd (6) determining.

Combining the analysis of the step 2.1) and the step 2.2), obtaining a mechanism of capacitance voltage unevenness: the equation (5) shows that the capacitor voltage unevenness has an accumulation characteristic, so that the capacitor voltage unevenness changes in real time along with different action vectors of the inverter; the formulas (8) and (9) show that the capacitors C on the direct current sides of the upper H bridge and the lower H bridge are arranged in the same time period₁,C₂,C₃,C₄The capacitance voltage variation is different due to different charging and discharging sizes; from equation (13), the capacitance C and the load can be seen

Switching frequency f_sInverter output voltage u_oSuch physical factors can affect the variation of the capacitor voltage unevenness in real time.

3) Mathematical model for uneven capacitor voltage

The method of combining component superposition and two-port equivalent circuit is adopted to establish a first-order ordinary differential equation model of capacitor voltage unevenness from the angles of capacitor voltage unevenness switching function and capacitor voltage unevenness current, and the model is solved

3.1) two-port equivalent circuit model

According to the superposition principle, the output voltage u_oIt can be equivalent to a superposition of two components: one part is the output voltage u of the inverter under the ideal condition that the capacitor voltage is completely balanced_o1The other part is equivalent capacitance voltage source delta U with uneven capacitance voltage_h1Induced inverter output voltage u_o2. In order to realize equivalent component separation on the direct current side according to different voltage sources, the following variables are defined:

bus capacitor voltage U_Cx(x ═ 1,2,3,4) is represented by:

inverter output voltage u_oExpressed as:

u_o＝S_aU_C1-S_bU_C2+S_cU_C3-S_dU_C4(16)

combining the formulas (13) and (14) to obtain an output voltage u_oExpression:

order S_t1＝S_a+S_b，S_d1＝S_a-S_b，S_t2＝S_c+S_d，S_d2＝S_c-S_dFormula (17) can proceedOne step is represented as:

wherein U is_HThe voltage value of the ideal condition without the uneven voltage of the capacitor is equivalent to the voltage value of a constant voltage source, U _d12 and U_d2And/2 is the capacitance voltage mean of CH1 and CH2, respectively. According to the equation (18), a two-port equivalent circuit of the single-phase NPC type H-bridge cascade inverter shown in fig. 5 is obtained.

According to the equivalent circuit shown in FIG. 5, the upper H-bridge capacitor voltage unevenness function DeltaU_h1(τ) can be expressed as:

a current i causing a capacitor voltage unevenness in a coupling formula (11)_c1The expression is as follows:

Δ U within one modulation wave period_h1(τ) can be expressed as a piecewise function:

according to sine wave symmetry, Delta U_h1The non-uniform boundaries in both the positive and negative half cycles are equal, so only the non-uniform boundaries of the positive half cycle are solved. The model contains a switching function S of capacitor voltage unevenness_tx(x is 1,2) and the uneven capacitor voltage component U of the lower H-bridge_d2These three variables result in a time-varying coupling of the model directly to Δ U over a complete fundamental period_h1The solution (tau) is complex and therefore the model needs to be simplified approximately.

3.2) model approximation

Switching function S for coupling component and capacitance voltage unevenness in model_txAre respectively carried out asThe following analyses were performed: due to U_d2Is a time variable, subtending Δ U at different times_h1The degree of influence of (c) is different. When U is turned_d2At 0, the coupled component pair DeltaU_h1No influence is caused, the voltage-sharing algorithm has the characteristic of over-regulation, and when the voltage of the upper H-bridge capacitor is uneven and reaches the peak value, the action vector is finished and the voltage of the lower H-bridge capacitor is uneven and U is not even_d2Adjustment of (2), the capacitor voltage of the lower H-bridge is not uniform U_d2Reaching the minimum value, the next switching cycle will be shifted to the pair U_d1And (4) adjusting. When external factors such as switching frequency, capacitance and the like meet the conditions, the voltage at U is increased_d1(t_m)＝U_d1maxNear the time U_d2(t_m) Can be approximated as 0, which means at t_mWithin the neighborhood of Δ t, the coupling component U_d2For delta U_h1The influence of (a) can be basically ignored, and the expression of the voltage unevenness of the capacitor in the positive half period of the upper H bridge is as follows:

switching function S due to capacitor voltage non-uniformity_txThe change in each fundamental wave period is irregular, and S of the whole voltage equalizing process is directly compared_txIt is difficult to express as a time-varying function. According to the control characteristics of the voltage-sharing algorithm, at t_mIn the neighborhood, S_txThe value law of (1) is shown in FIG. 6, U_d1max>0 and U_d1max< 0 time S_txThe values of (a) are respectively shown in fig. 7 and fig. 8, and the mathematical expressions are as follows:

since the step function shown in equation (23) is subjected to fourier transform, and the harmonic is found to be an odd harmonic as a main component, the step function is approximated by a series of sine functions:

although the formula (24) can relatively accurately represent S_txHowever, the series terms bring inconvenience to the modeling. To simplify the model, the harmonic component was analyzed for the CH1 voltage uneven current i_c1The positive half-cycle expression of equation (24) ignores the coupling component and is expressed as:

analysis S_t1And S_d1+S_d2Product sum

The characteristics of the terms, it has been found that S can be used in the symmetrical neighborhood of the moment of the uneven peak of the capacitor voltage_t1Approximation of fundamental component in place of S_t1I.e. by

ω_s1As a function of the switching S_t1The angular frequency of the wave is such that,

is S_t1Load power factor angle.

According to the model approximation condition, the establishment and solving range of the model are both (t)_m-△t,t_m+. at). When the inverter actually works, the inverter is limited by hardware conditions and actual working conditions, the variation ranges of the capacitance, the switching frequency, the power factor, the impedance and the modulation ratio are limited, and the established model definition domain is shown in table 2.

TABLE 2 definition of elements

And (3) simultaneously carrying out derivation on two sides of the formula (22) to obtain:

the solution of equation (26) is:

wherein p (τ) and Q (τ) are each

Will be provided with

(iii) belt-in (27), yielding:

in the formula

And

respectively for load to modulated wave u_rAnd a switching function S_t1Angle of power factor of omega_rAnd ω_s1Are each u_rAnd S_t1Angular frequency, Z is the load impedance, r₁And r₂Is an indefinite integral constant term. Since the indefinite integral of equation (28) does not have an analytical solution, it is necessary to approximate it, and in order to solve the model while maintaining the calculation accuracy, the observation "time window" is further narrowed to t_mOne switching period T being central_sInner, i.e. Δ t 1/2f_sThe time range is (t)_m-0.5T_s,t_m+0.5T_s) According to the median theorem of integral, the indefinite integral term in equation (28) is approximately expressed as:

xi is a median theorem indefinite term with a value range of t_m-0.5T_s≤ξ≤t_m+0.5T_s，k₁Is the power factor angle coefficient resulting from the interval reduction approximation. Let t be xi and t_mThe difference xi can be represented by t_mExpressed as xi ═ t_m+ t, combining equations (28) and (29), the capacitance-voltage variation boundary model can be obtained as:

in the formula, r is an indefinite integral constant term, a sine function exists in an index part in the model, the function form is still complex, and a first-order Taylor formula is utilized to approximately process the sine function of the index part to obtain a practical mathematical model of a first-order differential equation of uneven capacitance and voltage:

equation (31) is a final obtained capacitance-voltage non-uniformity function model, but some unknown parameters still exist in the model, so that the relevant parameters need to be further determined by combining actual application conditions of the inverter.

3.3) model solution

And (3) determining the unknown parameters in the mathematical model of the formula (31) by combining the actual working conditions of the inverter.

①S_txFundamental angular frequency omega_s1

S_txThe fundamental frequency is determined by the size of the observation "time window" Δ t. When the inverter normally works, the switching frequency is generally not lower than 1kHz, because S_txAt t_mOccupying a plurality of switching periods nearby, and calculating S through simulation analysis under different switching frequencies_txHas an average number of occupied cycles of 4.56, corresponding to f_s1＝219Hz，ω_s1＝1381rad/s。

②S_txAngle of power factor

Theoretically, S_txPower factor angle of fundamental angular frequency

And load power factor angle

Satisfying the power triangle as shown in fig. 9, their relationship is:

in the formula f_s1Is S_txFundamental frequency, f_rIs the modulated wave frequency. Can solve

And

for simplicity of analysis, at t_mAnd the relationship is approximately expressed by adopting first-order Taylor and linear superposition, and the formula (33) is obtained:

power factor angle coefficient k₁

Power factor angle coefficient k₁Correction coefficient, S, generated by approximation of an indefinite integral term_txThe higher the average frequency, the smaller the integration interval and the smaller the corresponding correction coefficient. When S is_txWhen the average frequency is 219Hz, the correction coefficient is 1, and S is calculated_txWhen the average frequency is increased to 1kHz, the corresponding zoom factor is 0.219, and Table 3 shows the difference S_txRelation between average frequency and zoom ratio, the average zoom ratio is k₁＝0.118。

TABLE 3S_txAverage frequency and scaling factor relationship

Fourthly indefinite term t of median theorem

According to the approximation process analysis of the indefinite integration of the formula (29), when the switching frequency is 1kHz, the maximum value of t is 0.0005; the maximum value of t is 0.000166 when the switching frequency is 3 kHz. In the switching frequency range of 1kHz to 3kHz, the switching frequency at equal intervals was taken, and the average value was taken as the value of t in the model, and t was calculated to be 0.00027.

TABLE 4 switching frequency vs. t

Indefinite integral term r and peak time t_m

The uncertain integral term r is positioned in an exponential part, determines the magnitude of the capacitor voltage unevenness, is related to multiple factors such as the voltage grade of the inverter, the capacitance magnitude, the switching frequency, the load property, the modulation ratio and the like, and leads to the model complication and difficult solution through direct analysis in theory. Thus a simple method is to use U_d1The empirical value is approximated by using equation (34).

When τ is t_mOf (1), U'_d1(t_m) When 0 is obtained, the following equation holds in combination with (26):

U_d1(t_m)S_t1(t_m)+2u_r(t_m)U_H＝0 (35)

the peak time t can be obtained according to the formula_m。

And (3) substituting the parameters into an equation (31), namely completing the mathematical modeling of the single-phase CHB-NPC inverter capacitance-voltage unevenness.

4) Capacitance voltage mura sensitivity analysis

Sensitivity analysis is a mathematical method for researching the degree of influence of independent variables on dependent variables, and can be used for evaluating the contribution of each factor to the uneven capacitance and voltage. Since the model application range is within the domain space shown in table 2, the analysis was performed by the local sensitivity method. In order to avoid the complexity of direct derivation, the sensitivity is calculated by using finite difference, the basic principle of the finite difference is to give a small change to an independent variable in a defined domain, the finite difference calculation is used for approximately replacing derivative operation, and when the change step length of the independent variable is fixed, the larger the output change is, the more sensitive the independent variable is. The sensitivity calculation formula is as follows:

in the formula x₁，x₂Two operating mode states DeltaU respectively representing factor x_h1(x₁) And Δ U_h1(x₂) Are respectively represented at x₁，x₂The capacitor voltage under the working condition is not mean.

The inverter reference operating conditions were selected as in table 5 in combination with the actual inverter operating conditions studied.

TABLE 5 reference operating mode of each element

When the sensitivity of one factor is studied, the other factors are controlled to be constant values. Dividing the respective variable ranges shown in Table 2 into 10 equal parts at equal intervals, and defining the relative sensitivity of the influencing factor x in each equal part as RS_xThe calculation formula is formula (37), and the overall sensitivity is defined as SS_xThe calculation formula is formula (38).

Table 6 shows the results of the relative sensitivity and the overall sensitivity calculations in 10 aliquot zones.It can be seen that the relative sensitivity of the factors RS in the different zones_xThe sizes are different. Overall relative sensitivity SS_xThe method comprises the following steps from large to small: modulation ratio, capacitance, impedance, switching frequency, and power factor. As the actual working condition of the inverter is a point in the defined domain space, the sensitivity of the corresponding interval is selected for comparative analysis according to the actual condition during engineering application, and the relative sensitivity RS of each interval_xHas more practicability.

TABLE 6 relative sensitivity of the factors in the action section

In order to verify the accuracy of the inverter capacitor voltage unevenness model, a capacitor voltage unevenness mathematical model containing a plurality of factors is simulated. And (3) operating 10 fundamental wave periods under different working conditions, averaging the maximum value of the uneven capacitor voltage in each period, and taking the average value as the uneven capacitor voltage value under the working condition. The simulation sampling method comprises the following steps: the modulation ratio and the power factor are in the range of (0, 1), equal-interval simulation is carried out, and the other variables are respectively subjected to equal-interval sampling according to a certain multiple relation on the basis of the standard working condition of the table 5.

FIGS. 10-14 show the modulation ratio, capacitance magnitude, switching frequency, power factor, impedance magnitude and Δ U_h1A graph of the relationship (c). In order to facilitate unified comparison, per-unit calculation is carried out on the uneven capacitor voltage, and the reference value is the voltage U of the constant-voltage source at the direct-current side_H. The delta U obtained by simulation_h1Compared with the calculation result of the model, the variation trends of the two are basically consistent, and the model is approximate and cannot be completely coincided with the simulation result. From the perspective of engineering applications, given an error bandwidth of 5%, the simulation data is substantially distributed within the error bandwidth centered on the model calculation.

Table 7 shows the fitting determination coefficient R of the simulated value and the calculated value². The fitting effect of the modulation ratio and the switching frequency is poor, and the modulation ratio R is poor²At 0.9257, switching frequency R²Is 0.8720, best fitting effect of power factor, R²Was 0.9817.

TABLE 7 analysis of model fitting Performance

In order to obtain more capacitance voltage waveforms under experimental conditions, equally spaced experiments with the reference condition shown in table 5 were performed on an RT-Lab experimental platform, and comparison of theoretical calculation values and experimental results are shown in fig. 15 to 19.

It can be seen that the error bandwidth of 5% of the model calculation result basically covers the capacitance voltage uneven value measured by the experiment, which shows that the model can describe the variation trend of the capacitance voltage uneven value. Fitting decision coefficient R of model calculated value and experimental data²The following were used: modulation ratio R²0.8870; magnitude of capacitance R²0.9749; switching frequency R²0.7267; power factor R²0.9801; magnitude of impedance R²The experimental results are in substantial agreement with theoretical calculations, 0.9578.

It is to be understood that the foregoing is by way of example only and is not intended as limiting the embodiments. It will be apparent to those skilled in the art that other variations and modifications can be made in the specific embodiments based on the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Those not described in detail in this specification are within the skill of the art.

Claims (3)

1. A single-phase NPC type H bridge cascaded inverter capacitance-voltage unevenness modeling method based on pulse jump SVPWM is characterized in that a single-phase CHB-NPC inverter topological structure is composed of four NPC half-bridge circuits, two NPC half-bridges are connected in parallel to form a five-level NPC type H bridge, the two H bridges are cascaded, the upper H bridge is a cascaded unit CH1, the lower H bridge is a cascaded unit CH2, the cascaded unit CH1 is composed of a bridge arm a and a bridge arm b, and the cascaded single-phase NPC type H bridge cascaded inverter is single in structureElement CH2 is composed of bridge arm c and bridge arm d, S_xRepresents the x-th bridge arm state, x ═ a, b, c, d; the method is characterized in that: the capacitor voltage unevenness modeling method comprises the following steps:

1) the capacitor voltage unevenness mechanism analyzes equivalent circuits when different vectors act, influences of the capacitor voltage unevenness are determined to include capacitance size, switching frequency, modulation ratio, load impedance and power factor, and the expression of the capacitor voltage unevenness is as follows:

and obtaining the current expression of the capacitor voltage unevenness to cause the voltage unevenness Delta U of the upper H bridge_h1Current i of_c1The expression is as follows:

delta U causing lower H bridge voltage non-uniformity_h2Current i of_c2The expression is as follows:

where k denotes the kth vector contribution, i_LkRepresents the load current, S, at the time of the k-th vector action_akRepresents the state of the bridge arm a at the time of the k-th vector, S_bkRepresents the state of the bridge arm b at the time of the kth vector, S_ckRepresents the state of the bridge arm c at the time of the kth vector, S_dkRepresenting the state of a bridge arm d at the k vector;

2) by combining component superposition and two-port equivalent circuit, a first-order ordinary differential equation model of capacitor voltage unevenness is established from the angles of capacitor voltage unevenness switching function and capacitor voltage unevenness current, and a first-order differential equation mathematical model formula (31) of capacitor voltage unevenness is solved for unknown parameters of the model by combining the actual working conditions of the inverter

Wherein, U_HIs a constant voltage source voltage at the DC side of the H bridge, U_d1(t_m) The/2 is the uneven peak value of the capacitor voltage in one fundamental wave period, C is the capacitance value of the supporting capacitor, | Z | is the load impedance of the inverter,

as the load power factor angle, omega_rFor modulating the fundamental angular frequency of the wave, m is the modulation ratio, f_sIs the switching frequency. The unknown parameter comprises S_txFundamental angular frequency omega_s1、S_txAngle of power factor

Power factor angle coefficient k₁Median theorem indefinite term t, indefinite integral term r and peak time t_m；

After the solution is completed, the parameter S is added_txFundamental angular frequency omega_s1、S_txAngle of power factor

Power factor angle coefficient k₁Median theorem indefinite term t, indefinite integral term r and peak time t_mAnd (31) the mathematical modeling of the capacitor voltage unevenness of the single-phase CHB-NPC inverter is completed.

2. The modeling method for the voltage unevenness of the capacitor of the single-phase NPC type H-bridge cascaded inverter based on the pulse-hopping SVPWM as claimed in claim 1, is characterized in that: in the step 2), the first-order differential equation mathematical model of the capacitor voltage unevenness is subjected to model approximation by adopting a time scale reduction method, the switch function of the capacitor voltage unevenness is subjected to sine, and the coupling condition is decoupled.

3. The modeling method for the voltage unevenness of the capacitor of the single-phase NPC type H-bridge cascaded inverter based on the pulse-hopping SVPWM as claimed in claim 1, is characterized in that: and 2) after mathematical modeling of the capacitor voltage unevenness of the single-phase CHB-NPC inverter in the step 2), analyzing the sensitivity of the capacitor voltage unevenness, and sorting the factors influencing the capacitor voltage unevenness, wherein the factors influencing the capacitor voltage unevenness comprise the capacitor size, the switching frequency, the modulation ratio, the load impedance and the power factor.

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