CN109302145B - A kind of photovoltaic array I-V characteristic detection device and detection method - Google Patents

Abstract

The present invention relates to a kind of photovoltaic array I-V characteristic detection device and its detection methods, setting charging measurement circuit is that two unequal capacitors of capacitance are connected in parallel, it is respectively formed respective charging measurement branch, control circuit is used for the on-off by least one charging measurement branch of control, change the capacitance of the charging measurement circuit of access photovoltaic array, and acquisition obtains the charging current and its both end voltage of charging measurement circuit under different capacitances, it is calculated according to the charging current for the charging measurement circuit for acquiring acquisition under different capacitances and both end voltage and obtains line inductance and line resistance, the I-V characteristic for obtaining photovoltaic array is calculated using line inductance and line resistance, the present invention can effectively improve the precision of photovoltaic array I-V characteristic detection, its is easy to operate, safety, it is small in size, it is light-weight.

Description

A kind of photovoltaic array I-V characteristic detection device and detection method

Technical field

The present invention relates to a kind of detection device and its detection method, specifically a kind of photovoltaic array I-V characteristic inspection Survey device and its detection method.

Background technique

Photovoltaic array is the core component of photovoltaic plant, even also needing in tens years after putting into operation The I-V characteristic of photovoltaic array is detected, accurately to obtain photovoltaic system generated energy, maintenance easy to repair.Photovoltaic array Detection device be it is a kind of photovoltaic array is detected at the scene, to obtain the device of the accurate I-V characteristic curve of photovoltaic array.

Photovoltaic array I-V characteristic detection method in the prior art is the method to bulky capacitor charging, in photovoltaic array Both ends shunt capacitance, it is by power resistor that the electric quantity consumption of capacitor remnants is complete first when testing beginning, so that capacitor is kept Zero original state, impedance are very low almost nil, it is believed that the electric current of sampling apparatus acquisition at this time is short circuit current, when capacitor charging knot Shu Hou, impedance is very big, and charge circuit is equivalent to open circuit, it is believed that the voltage of sampling apparatus acquisition at this time is open-circuit voltage.In electricity In the charging process of appearance, that is, the impedance of resistance is thought from zero to infinity, the load for being equivalent to photovoltaic array increases from zero to nothing It is poor big, by recording the situation of change of this process voltage and electric current, the I-V characteristic curve of photovoltaic array is obtained, and showing It is shown on screen.

But there are line inductance and line resistance when due to the detection of photovoltaic array I-V characteristic, line inductance and resistance meeting It is divided when capacitor charging detection, existing photovoltaic array I-V characteristic detection method only has detected on capacitor I-V characteristic curve but has ignored the influence of line inductance and resistance, and causing last measurement result is not accurate photovoltaic battle array Column I-V characteristic.Simultaneously as the presence of line inductance, electric current can not be mutated in zero moment, so electric at the beginning Holding voltage is zero, and electric current is also zero, will have biggish error for the measurement of short circuit current, eventually leads to I-V characteristic song There are biggish errors for line.This method will improve the precision of measurement, it is necessary to increase capacitance, therefore increase volume and weight.

Summary of the invention

The present invention be to avoid above-mentioned the deficiencies in the prior art, provide it is a kind of it is small in size, light weight and cost is low and precision is high Photovoltaic array I-V detection device and its detection method.

The present invention adopts the following technical scheme that in order to solve the technical problem

Photovoltaic array I-V characteristic detection device of the present invention includes control circuit, charging measurement circuit and display circuit, spy Point is: the charging measurement circuit is that two unequal capacitors of capacitance are connected in parallel, and two capacitors are respectively formed respectively From charging measurement branch, i.e. the first charging measurement branch and i.e. the second charging measurement branch, the control circuit is for passing through The on-off of at least one charging measurement branch is controlled, changes the capacitance of the charging measurement circuit of access photovoltaic array, and not The charging current and its both end voltage that charging measurement circuit is obtained with acquisition under capacitance, obtain according to acquiring under different capacitances Charging measurement circuit charging current and both end voltage calculate obtain line inductance L and line resistance R, utilize the line electricity Feel L and line resistance R and calculates the I-V characteristic for obtaining photovoltaic array.

The characteristics of photovoltaic array I-V characteristic detection device of the present invention lies also in: the control circuit includes that Current Voltage is adopted Sample circuit and DSP signal processing circuit for carrying out data processing, the current-voltage sampling circuit include and the charging The current sampling switch S of test circuit in parallel connection and the power resistor being connected in parallel with capacitor, the current-voltage sampling Circuit under different capacitances acquisition obtain the charging current and both end voltage of the charging measurement circuit, respectively as adopting Sample electric current and sampled voltage.

The characteristics of photovoltaic array I-V characteristic detection device of the present invention, lies also in: the circuit structure of the charging measurement branch Are as follows: using one end of capacitor on-off switch as the terminal A of charging measurement branch, using the forward end of diode as charging measurement branch Terminal B, capacitor is arranged in series between capacitor on-off switch and the negative pole end of diode；One end of the power resistor The terminal A of charging measurement branch is connected to by power resistor on-off switch, the other end of power resistor is connected to diode Negative pole end forms the parallel-connection structure of power resistor and capacitor；The charging measurement branch is connected with its terminal A and terminal B parallel connection It connects at the both ends of charging measurement circuit.

The characteristics of photovoltaic array I-V characteristic test method of the present invention is: the application photovoltaic array I-V characteristic tests dress It sets, is tested as follows:

Step 1, in 0~t₁Stage, closed path sampling switch S disconnect the capacitor on-off in each charging measurement branch Switch and power resistor on-off switch, the capacitor in each charging measurement branch are maintained at zero original state, charging measurement circuit It is short-circuited, due to the effect of line inductance L, sample rate current is gradually increased by 0, and in t₁Moment reaches maximum value, records t₁Moment Sample rate current I₀, the sample rate current I₀For photovoltaic array short circuit current；

Step 2, in t₁~t₂Stage, turn-off current sampling switch S, the capacitor connected in the first charging measurement branch are logical It disconnects and closing, capacitor of the photovoltaic array into the first charging measurement branch charges, in t₂Moment the first charging measurement branch The charging current of middle capacitor is reduced to zero, and charging process terminates, and records t₂The sampled voltage V at moment₁And this stage current Voltage response P1, the sampled voltage V₁For the open-circuit voltage of the first charging measurement branch；

Step 3, in t₂~t₃Stage disconnects the capacitor on-off switch in the first charging measurement branch, connects the second charging The capacitor on-off switch in branch is tested, capacitor of the photovoltaic array into the second charging measurement branch charges, in t₃ The charging current of capacitor is reduced to zero in moment the second charging measurement branch, and charging process terminates, and records t₃The sampling at moment Voltage V₂And this stage current voltage response P2, the sampled voltage V₂For the open circuit electricity of the second charging measurement branch Pressure；

Step 4, in t₃~t₄Stage is closed capacitor on-off switch in the first charging measurement branch, and is closed first and fills Power resistor on-off switch in electrical testing branch and the second charging measurement branch, using power resistor in t₄Moment completes to first The electric discharge of capacitor in charging measurement branch and the second charging measurement branch；

Step 5, in t₄~t₅Stage disconnects the power resistor on-off in the first charging measurement branch and the second test branch Switch, capacitor of the photovoltaic array simultaneously into the first charging measurement branch and the second charging measurement branch charges, in t₅ The charging of capacitor is zero in moment the first charging measurement branch and the second charging measurement branch, and charging process terminates, record t₅The sampled voltage V at moment₃And this stage current voltage response P3, the sampled voltage V₃For charging measurement circuit Open-circuit voltage；

Step 6, the same sampled current value I of setting_k,

The corresponding electric current I is obtained in current-voltage characteristic curve P1_kSampled voltage U₁；

The corresponding electric current I is obtained in current-voltage characteristic curve P2_kSampled voltage U₂；

The corresponding electric current I is obtained in current-voltage characteristic curve P3_kSampled voltage U₃；

Set another sampled current value I_k+1

Determine the I in current-voltage characteristic curve P1_k+1With I_kBetween time interval be Δ t₁；

Determine the I in current-voltage characteristic curve P2_k+1With I_kBetween time interval be Δ t₂；

Determine the I in current-voltage characteristic curve P3_k+1With I_kBetween time interval be Δ t₃；

It is calculated by formula (1) and obtains the sampled current value I in current-voltage characteristic curve P1, P2 and P3_kDifferential value d1, d2 And d3:

It is calculated using equation group (2) and obtains line inductance L and line resistance R:

Wherein U characterizes photovoltaic array end voltage；

Step 7, according to the line inductance L and line resistance R, optimize by error obtain photovoltaic array eliminate due to Photovoltaic array voltage value to be measured and current value after the error that line inductance L and line resistance R is generated；

Step 8, detection terminate, and the power resistor on-off being closed in the first charging measurement branch and the second test branch is opened It closes, the remaining capacity of each capacitor is all run out of, each capacitor is made to return to zero original state, is then turned off each power resistor On-off switch.

The characteristics of photovoltaic array I-V characteristic test method of the present invention, lies also in: error optimization be as follows into Row:

Step 5.1 repeats step 1 to step 6, obtains the n group data about line inductance L and line resistance R, utilizes formula (3) it calculates and obtains target function value Yi:

Y_i=L_i+R_iI_ki (3),

In formula (3), I_KiIt is I in i-th group of data_KValue, Li is the line electricity inductance value in i-th group of data, and Ri is i-th group of number The value of line resistance in, i=1,2,3...n；

Step 5.2 defines least square method fitting function such as formula (4):

Y_i=L+RI_ki(4),

By I_kiWith calculate the target function value Yi obtained according to fitting function shown in formula (4), using least square method into Row curve matching obtains least square method fit curve equation group (5):

Step 5.3 enables to the smallest line inductance L of error and line electricity using the equation group (5) calculating acquisition The value of R is hindered, error optimization is completed.

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

1, the present invention can efficiently reduce the volume and again of detection device by the way of two capacitor charged in parallels Amount, and detection speed can be improved.

2, the present invention takes voltage sample point at charging measurement circuit both ends, eliminates the detection of line inductance open-circuit voltage Error, improve the detection accuracy of open-circuit voltage.

3, the present invention has fully considered the influence that line inductance and resistance detect photovoltaic array I-V characteristic, and three groups are not After same capacitor carries out I-V characteristic detection, the value of line inductance and resistance is solved, photovoltaic array I- can be greatly improved The precision of V Characteristics Detection restores true photovoltaic array I-V characteristic curve.

4, invention increases short circuit current sampling switch structure, fully considered that electric current is not since line inductance exists The case where capable of mutating, can greatly improve the precision of short circuit current detection.

Detailed description of the invention

Fig. 1 is photovoltaic array I-V characteristic test device electrical block diagram of the present invention；

Fig. 2 is short circuit currents instrumentation plan of the present invention；

Capacitor voltage at both ends and current diagram when Fig. 3 is charging measurement of the present invention；

Fig. 4 is photovoltaic array I-V characteristic test method schematic diagram in the present invention；

Fig. 5 is the I-V characteristic curve synoptic diagram with line inductance error；

Fig. 6 is the photovoltaic array I-V detection curve schematic diagram obtained using test device shown in Fig. 1；

Fig. 7 is another embodiment electrical block diagram of test device in the present invention.

Specific embodiment

Referring to Fig. 1, photovoltaic array I-V characteristic detection device includes control circuit 2, charging measurement circuit 1 in the present embodiment With display circuit.Charging measurement circuit 1 is that two capacitances unequal capacitor C1, C2 are connected in parallel, using two capacitors Device, which is connected in parallel, can effectively reduce device volume and weight, and two capacitors are respectively formed respective charging measurement branch, i.e., First charging measurement branch and i.e. the second charging measurement branch, control circuit 2 are used for through at least one charging measurement branch of control The on-off on road, changes the capacitance of the charging measurement circuit of access photovoltaic array, and acquires and charged under different capacitances The charging current and its both end voltage for testing circuit, according to the charging for the charging measurement circuit for acquiring acquisition under different capacitances electricity Stream and both end voltage, which calculate, obtains line inductance L and line resistance R, is calculated using line inductance L and line resistance R and obtains photovoltaic The I-V characteristic of array, while eliminating as line resistance R and line inductance L to caused by photovoltaic array I-V characteristic to be measured measurement Error.

As shown in Figure 1, control circuit 2 is including current-voltage sampling circuit and for carrying out data processing in the present embodiment DSP signal processing circuit, current-voltage sampling circuit include the current sampling switch S being connect with charging measurement circuit in parallel and The power resistor R being connected in parallel with capacitor_P1、R_P2, current-voltage sampling circuit filled for acquiring under different capacitances The charging current and both end voltage of electrical test circuit, respectively as sample rate current and sampled voltage.

As shown in Figure 1, in the present embodiment, the circuit structure of charging measurement branch are as follows: with one end of capacitor on-off switch For the terminal A of charging measurement branch, using the forward end of diode as the terminal B of charging measurement branch, capacitor is arranged in series in Between capacitor on-off switch and the negative pole end of diode；One end of power resistor is connected to by power resistor on-off switch to be filled The terminal A of electrical testing branch, the other end of power resistor are connected to the negative pole end of diode, form power resistor and capacitor Parallel-connection structure；Charging measurement branch is connected in the both ends of charging measurement circuit 1 in parallel with its terminal A and terminal B.

Photovoltaic array I-V characteristic test method is using photovoltaic array I-V characteristic test device, by as follows in the present embodiment Step is tested:

Step 1, as shown in Fig. 2, in 0~t₁Stage, closed path sampling switch S are disconnected in each charging measurement branch Capacitor on-off switch and power resistor on-off switch, the capacitor in each charging measurement branch are maintained at zero original state, fill Electrical test circuit is short-circuited, and due to the effect of line inductance L, electric current cannot be mutated, and sample rate current is gradually increased by 0, and in t₁ Moment reaches maximum value, records t₁The sample rate current I at moment₀, sample rate current I₀For photovoltaic array short circuit current.

Step 2, as shown in figure 3, in t₁~t₂Stage, turn-off current sampling switch S are connected in the first charging measurement branch Capacitor on-off switch S₁₁, capacitor of the photovoltaic array into the first charging measurement branch charge, capacitor on-off switch S₁₁Just when closure, the charging current for flowing through capacitor C1 is the short circuit current I of photovoltaic array 1₀, as photovoltaic array starts to fill Electricity, charging current slowly reduce, and the load for being equivalent to photovoltaic array slowly reduces, finally in t₂Moment the first charging measurement branch The charging current of middle capacitor is reduced to zero, and charging process terminates, and records t₂The sampled voltage V at moment₁And this stage current Voltage response P1, sampled voltage V₁For the open-circuit voltage of the first charging measurement branch.As shown in figure 3, being opened in capacitor on-off When Guan Gang is closed, zero original state of capacitor holding at this time, voltage 0, then under the charging of photovoltaic array, the first charging measurement Circuit both end voltage gradually rises, due to the effect of line inductance L, during charging current decline, meeting on line inductance L The voltage of a negative sense is generated, this causes the voltage at the first test charge circuit both ends to generate one and is higher than the open circuit of photovoltaic array 1 The peak value of voltage, as charging current is reduced to 0, the first test charge circuit both end voltage gradually decreases down open-circuit voltage V₁。

Step 3, in t₂~t₃Stage disconnects the capacitor on-off switch S in the first charging measurement branch₁₁, connect second Capacitor on-off switch S in charging measurement branch₂₁, capacitor of the photovoltaic array into the second charging measurement branch filled Electricity, in t₃The charging current of capacitor is reduced to zero in moment the second charging measurement branch, and charging process terminates, and records t₃Moment Sampled voltage V₂And this stage current voltage response P2, sampled voltage V₂For the open circuit electricity of the second charging measurement branch Pressure.

Step 4, in t₃~t₄Stage is closed capacitor on-off switch S in the first charging measurement branch₁₁, and it is closed the Power resistor on-off switch S in one charging measurement branch and the second charging measurement branch₁₂、S₂₂, utilize power resistor R_P1、R_P2In t₄Moment completes the electric discharge to capacitor in the first charging measurement branch and the second charging measurement branch.

Step 5, in t₄~t₅Stage disconnects the power resistor on-off in the first charging measurement branch and the second test branch Switch S₁₂、S₂₂, photovoltaic array simultaneously capacitor C1, C2 into the first charging measurement branch and the second charging measurement branch into Row charging, in t₅The charging current of capacitor is zero in moment the first charging measurement branch and the second charging measurement branch, is filled Electric process terminates, and records t₅The sampled voltage V at moment₃And this stage current voltage response P3, sampled voltage V₃To fill The open-circuit voltage of electrical test circuit.

Step 6, as shown in figure 4, setting same sampled current value I_k,

Corresponding current I is obtained in current-voltage characteristic curve P1_kSampled voltage U₁；

Corresponding current I is obtained in current-voltage characteristic curve P2_kSampled voltage U₂；

Corresponding current I is obtained in current-voltage characteristic curve P3_kSampled voltage U₃；

Set another sampled current value I_k+1

Determine the I in current-voltage characteristic curve P1_k+1With I_kBetween time interval be Δ t₁

Determine the I in current-voltage characteristic curve P2_k+1With I_kBetween time interval be Δ t₂

Determine the I in current-voltage characteristic curve P3_k+1With I_kBetween time interval be Δ t₃

It is calculated by formula (1) and obtains the sampled current value I in current-voltage characteristic curve P1, P2 and P3_kDifferential value d1, d2 And d3:

It is calculated using equation group (2) and obtains line inductance L and line resistance R:

Wherein U characterizes photovoltaic array end voltage.

Step 7, according to line inductance L and line resistance R, optimize by error and obtain photovoltaic array and eliminating due to route Photovoltaic array voltage value to be measured and current value after the error that inductance L and line resistance R is generated；

Step 8, detection terminate, the power resistor on-off switch being closed in the first charging measurement branch and the second test branch S₁₂、S₂₂, the remaining capacity of each capacitor is all run out of, each capacitor is made to return to zero original state, is then turned off each power Resistance on-off switch.

In specific implementation, error optimization is to carry out as follows:

Step 1.1 repeats step 1 to step 6, obtains the n group data about line inductance L and line resistance R, utilizes formula (3) it calculates and obtains target function value Yi:

Y_i=L_i+R_iI_ki (3)

In formula (3), I_KiIt is I in i-th group of data_KValue, Li is the line electricity inductance value in i-th group of data, and Ri is i-th group of number The value of line resistance in, i=1,2,3...n.

Step 1.2 defines least square method fitting function such as formula (4):

Y_i=L+RI_ki (4)

By I_kiWith calculate the target function value Yi obtained according to fitting function shown in formula (4), using least square method into Row curve matching obtains least square method fit curve equation group (5):

Step 1.3 enables to error the smallest line inductance L's and line resistance R using equation group (5) calculating acquisition Value completes error optimization.

As shown in figure 5, being the photovoltaic array I-V characteristic to be measured for not considering the error-detecting of line inductance L and resistance R and going out Curve, due to the effect of line inductance L, electric current cannot be mutated, and when voltage is 0, electric current is gradually increased to maximum from 0 Value, causes when measuring at the beginning, and the electric current of detection device measurement is not short circuit current, in the mistake of charging current decline The voltage that a negative sense can be generated on Cheng Zhong, line inductance L and line resistance R, leads to the measured value of photovoltaic array both end voltage Greater than the true value of photovoltaic array both end voltage, in contrast to as shown in fig. 6, using photovoltaic array I-V detection device of the invention The accurate photovoltaic array I-V curve detected, it can be seen that line inductance and line resistance will cause very big error, In After photovoltaic array I-V detection device measurement of the invention, hence it is evident that eliminate caused by line inductance and line resistance accidentally The precision of difference, detection greatly increases.

As shown in fig. 7, in charging measurement circuit, due to using two capacitor parallel connections to carry out third time charging detection Before, capacitor will carry out second of electric discharge, will increase the time of detection, can third capacitor in parallel in order to shorten detection cycle Device carries out third time measurement, to reduce second of the time discharged of capacitor, so as to shorten detection cycle.

Claims (2)

1. a kind of photovoltaic array I-V characteristic detection device, including control circuit, charging measurement circuit and display circuit, feature Be: the charging measurement circuit is that two unequal capacitors of capacitance are connected in parallel, and two capacitors are respectively formed respectively Charging measurement branch, i.e. the first charging measurement branch and i.e. the second charging measurement branch, the control circuit is for passing through control The on-off of at least one charging measurement branch is made, changes the capacitance of the charging measurement circuit of access photovoltaic array, and in difference Acquisition obtains the charging current and its both end voltage of charging measurement circuit under capacitance, is obtained according to acquisition under different capacitances The charging current and both end voltage of charging measurement circuit, which calculate, obtains line inductance L and line resistance R, utilizes the line inductance L and line resistance R calculates the I-V characteristic for obtaining photovoltaic array；

The control circuit includes current-voltage sampling circuit and the DSP signal processing circuit for carrying out data processing, described Current-voltage sampling circuit includes the current sampling switch S connecting with the charging measurement circuit in parallel and company in parallel with capacitor The power resistor connect, the current-voltage sampling circuit is for the acquisition acquisition charging measurement circuit under different capacitances Charging current and both end voltage, respectively as sample rate current and sampled voltage；

The circuit structure of the charging measurement branch are as follows: using one end of capacitor on-off switch as the terminal A of charging measurement branch, Using the forward end of diode as the terminal B of charging measurement branch, capacitor is arranged in series in capacitor on-off switch and diode Negative pole end between；One end of the power resistor is connected to the terminal A of charging measurement branch by power resistor on-off switch, The other end of power resistor is connected to the negative pole end of diode, forms the parallel-connection structure of power resistor and capacitor；The charging Test branch is connected in the both ends of charging measurement circuit in parallel with its terminal A and terminal B；

Realize that photovoltaic array I-V characteristic is tested as follows using the photovoltaic array I-V characteristic test device:

Step 1, in 0~t₁Stage, closed path sampling switch S, disconnect capacitor on-off switch in each charging measurement branch and Power resistor on-off switch, the capacitor in each charging measurement branch are maintained at zero original state, and charging measurement circuit is short-circuited, Due to the effect of line inductance L, sample rate current is gradually increased by 0, and in t₁Moment reaches maximum value, records t₁The sampling electricity at moment Flow I₀, the sample rate current I₀For photovoltaic array short circuit current；

Step 2, in t₁~t₂Stage, turn-off current sampling switch S, the capacitor on-off connected in the first charging measurement branch are opened It closes, capacitor of the photovoltaic array into the first charging measurement branch charges, in t₂It is electric in moment the first charging measurement branch The charging current of container is reduced to zero, and charging process terminates, and records t₂The sampled voltage V at moment₁And this stage current voltage Characteristic curve P1, the sampled voltage V₁For the open-circuit voltage of the first charging measurement branch；

Step 3, in t₂~t₃Stage disconnects the capacitor on-off switch in the first charging measurement branch, connects the second charging measurement Capacitor on-off switch in branch, capacitor of the photovoltaic array into the second charging measurement branch charges, in t₃Moment The charging current of capacitor is reduced to zero in second charging measurement branch, and charging process terminates, and records t₃The sampled voltage at moment V₂And this stage current voltage response P2, the sampled voltage V₂For the open-circuit voltage of the second charging measurement branch；

Step 4, in t₃~t₄Stage is closed capacitor on-off switch in the first charging measurement branch, and is closed the first charging and surveys Power resistor on-off switch in branch and the second charging measurement branch is tried, using power resistor in t₄Moment completes to charge to first Test the electric discharge of capacitor in branch and the second charging measurement branch；

Step 5, in t₄~t₅Stage disconnects the power resistor on-off switch in the first charging measurement branch and the second test branch, Capacitor of the photovoltaic array simultaneously into the first charging measurement branch and the second charging measurement branch charges, in t₅Moment The charging of capacitor is zero in one charging measurement branch and the second charging measurement branch, and charging process terminates, and records t₅Moment Sampled voltage V₃And this stage current voltage response P3, the sampled voltage V₃For the open circuit electricity of charging measurement circuit Pressure；

Step 6, the same sampled current value I of setting_k,

The sampled voltage U of the corresponding electric current Ik is obtained in current-voltage characteristic curve P1₁；

The corresponding electric current I is obtained in current-voltage characteristic curve P2_kSampled voltage U₂；

The corresponding electric current I is obtained in current-voltage characteristic curve P3_kSampled voltage U₃；

Set another sampled current value I_k+1

Determine the I in current-voltage characteristic curve P1_k+1With I_kBetween time interval be Δ t₁；

Determine the I in current-voltage characteristic curve P2_k+1With I_kBetween time interval be Δ t₂；

Determine the I in current-voltage characteristic curve P3_k+1With I_kBetween time interval be Δ t₃；

It is calculated by formula (1) and obtains the sampled current value I in current-voltage characteristic curve P1, P2 and P3_kDifferential value d1, d2 and d3:

It is calculated using equation group (2) and obtains line inductance L and line resistance R:

Wherein U characterizes photovoltaic array end voltage；

Step 7, according to the line inductance L and line resistance R, optimize by error and obtain photovoltaic array and eliminating due to route Photovoltaic array voltage value to be measured and current value after the error that inductance L and line resistance R is generated；

Step 8, detection terminate, the power resistor on-off switch being closed in the first charging measurement branch and the second test branch, will The remaining capacity of each capacitor all runs out of, and each capacitor is made to return to zero original state, is then turned off each power resistor on-off Switch.

2. photovoltaic array I-V characteristic detection device according to claim 1, it is characterized in that: error optimization is by such as Lower step carries out:

Step 5.1 repeats step 1 to step 6, obtains the n group data about line inductance L and line resistance R, utilizes formula (3) It calculates and obtains target function value Yi:

Y_i=L_i+R_iI_ki (3),

In formula (3), I_KiIt is I in i-th group of data_KValue, Li is the line electricity inductance value in i-th group of data, and Ri is in i-th group of data Line resistance value, i=1,2,3...n；

Step 5.2 defines least square method fitting function such as formula (4):

Y_i=L+RI_ki(4),

By I_kiThe target function value Yi obtained with calculating is according to fitting function shown in formula (4), using least square method march Line fitting, obtains least square method fit curve equation group (5):

Step 5.3 enables to error the smallest line inductance L's and line resistance R using the equation group (5) calculating acquisition Value completes error optimization.