KR102507827B1 - A Sensor Module for Detecting a Fault of a Solar Cell Module - Google Patents

Abstract

The present invention relates to a sensor module for detecting a fault of a solar cell module array connection direct current line. The sensor module for detecting a fault of a solar cell module array connection direct current line comprises: first and second switches (11a, 11b) installed between first and second lines (PL, NL) electrically connected to each other; first and second relays (12a, 12b) for electrically connecting the first and second switches (11a, 11b) and the first and second lines (PL, NL); a fourth relay (14) for electrically connecting the first and second lines (PL, NL); and fifth and sixth relays (15, 16) connected to the first and second lines (PL, NL), respectively. The present invention can detect ground faults or short circuit faults.

Description

A sensor module for detecting a fault of a solar cell module {A Sensor Module for Detecting a Fault of a Solar Cell Module}

The present invention relates to a sensor module for detecting a failure of a direct current line connected to a solar cell module array, and specifically, a solar cell module array direct current capable of detecting a failure occurring in a wiring structure of a solar cell module by the operation of relays electrically connected to each other. It relates to a sensor module for detecting a failure of a wire flow.

A photovoltaic power generation system of a photovoltaic power generating system (PV system) including a solar cell module, inverter, wiring, junction box, switchgear, or similar electric parts or facilities has a non-grounded structure. As a result, the ground fault current becomes a level of mA, making it difficult to detect, and if the fault continues, a fire may occur due to an arc or a human accident may occur due to contact. Therefore, it is necessary to apply a fault detection means having a high detection sensitivity capable of detecting a low fault current of less than 1 mA. LVDC (Low Voltage DC) may be applied in the photovoltaic power generation system, and an insulation monitoring device may be installed to detect a failure of the LVDC line. However, such an insulation monitoring device has a disadvantage that it is difficult to detect a failure of an individual input line of the junction box or to selectively block it. Although a residual current device may be applied to detect the fault current, leakage current may be generated due to a circuit formed between the ground and the LVDC system. And this may cause a malfunction of the ground fault protection relay of the AC system. Regarding failure detection of solar cell modules, Patent Registration No. 10-0918964 discloses a solar panel failure detection device. In addition, Patent Registration No. 10-2076978 discloses a photovoltaic power generation system having a failure detection unit. However, the prior art has a disadvantage that it is difficult to apply to fault detection of a photovoltaic power generation system. Therefore, it is necessary to create a fault detection means capable of detecting a malfunction current at the mA level while accurately determining a fault section of the photovoltaic power generation system.

The present invention is to solve the problems of the prior art and has the following object.

Prior Art 1: Patent Registration No. 10-0918964 (DK Co., Ltd., 2009.09.25. Announcement) Solar power generation system for detecting solar panel failure by distributed sensing Prior Art 2: Patent Registration No. 10-2076978 (Korea Institute of Civil Engineering and Building Technology, 2020.04.07. Announcement) Photovoltaic power generation system with failure detection unit

An object of the present invention is to provide a sensor module for detecting a failure of a DC line connected to a solar cell module array capable of detecting a ground fault or a short circuit fault installed in a photovoltaic power generation system.

According to a preferred embodiment of the present invention, a sensor module for detecting a failure of a DC line connected to a solar cell module array includes first and second switches installed between first and second lines electrically connected to each other; First and second relays electrically connecting the first and second switches and the first and second lines; A fourth relay electrically connecting the first and second lines; and fifth and sixth relays connected to the first and second lines, respectively.

According to another preferred embodiment of the present invention, a third relay connected between the first and second relays is further included.

According to another preferred embodiment of the present invention, it further includes a resistor connected in series to the first and second relays.

According to another preferred embodiment of the present invention, an ammeter installed on each of the first and second lines is further included.

According to another preferred embodiment of the present invention, the first and second lines connect between the solar cell module and the inverter.

The sensor module for detecting a failure of a DC line connected to a solar cell module array according to the present invention is installed in a solar power generation system to enable detection of a ground fault or short circuit fault. The sensor module according to the present invention has an error level of 0.5% or less in current measurement accuracy to suit the characteristics of the power generation principle of a photovoltaic module in which the difference between load current and fault current is not large. The sensor module according to the present invention has an advantage of preventing malfunction of the ground fault protection relay of the AC system while allowing failure determination in a string unit of sunlight. The sensor module according to the present invention makes it possible to detect a failure of each line of a power generation system. In addition, while enabling the detection of failures occurring in the photovoltaic array, it is possible to detect failures occurring in lines such as cable trays. By such failure detection, the power generation efficiency of the photovoltaic power generation facility is improved, and at the same time, the power generation safety is improved.

1 illustrates an embodiment of a sensor module for detecting a failure of a solar cell module according to the present invention.
2A and 2B show an embodiment in which a single sensor module is applied to detecting a ground fault.
3A to 6B show an embodiment in which a multi-sensor module is applied to detecting a ground fault.
7 illustrates an embodiment of a failure detection process by a sensor module according to the present invention.

Below, the present invention will be described in detail with reference to the embodiments presented in the accompanying drawings, but the embodiments are for a clear understanding of the present invention, and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so repeated descriptions are not made unless necessary for understanding the invention, and well-known components are briefly described or omitted, but the present invention It should not be understood as being excluded from the embodiment of.

1 illustrates an embodiment of a sensor module for detecting a failure of a solar cell module according to the present invention.

Referring to FIG. 1 , a sensor module for detecting a failure of a solar cell module includes first and second switches 11a and 11b installed between first and second lines PL and NL electrically connected to each other; first and second relays 12a and 12b electrically connecting the first and second switches 11a and 11b and the first and second lines PL and NL; A fourth relay 14 electrically connecting the first and second lines PL and NL; and fifth and sixth relays 15 and 16 connected to the first and second lines PL and NL, respectively.

The first and second lines PL and NL may be wires connected to positive and negative electrodes of a solar cell module, such as a solar cell, a solar cell module, a solar cell string, or a solar cell array, respectively. . The first and second lines PL and NL may be wires connecting a solar cell module and an inverter or junction box. The first and second lines PL and NL may extend parallel to each other, and the first and second lines PL and NL may be connected by the first and second switches 11a and 11b. The first and second switches 11a and 11b may have a function of operating the sensor module and may be connected in series with each other. A first relay 12a may be connected between the first switch 11a and the first line PL, and a first resistor R1 may be connected in series with the first relay 12a. A second relay 12b may be connected between the second switch 11b and the second line NL, and the second relay 12b and the second line NL may be connected in series by a second resistor R2. can When the first and second lines (PL, NL) are connected to the positive electrode (P) and the negative electrode (N) of the solar cell module, respectively, the first and second relays 12a and 12b respectively generate N polarity and P polarity ground fault currents. It may have a detection function. In addition, the resistors R1 and R2 connected to each of the relays 12a and 12b may have a function of limiting current flowing inside the sensor module. A third relay 13 may be connected between the first and second switches 11a and 11b, and one end of the third relay 13 may be grounded. The third relay 13 may have a function of detecting an overvoltage due to a ground fault, and in parallel with the third relay 13, a third resistor R3 for detecting the voltage inside the sensor module by the ground fault current is connected. can The fourth relay 14 may directly connect the first and second lines PL and NL to detect low voltage according to the short circuit of the first and second lines PL and NL. In addition, the fourth and fifth resistors R4 and R5 may be connected to the contacts of the fourth relay 14 and the first and second lines PL and NL, respectively. In addition, the fifth and sixth relays 15 and 16 may be connected in parallel to the fourth and fifth resistors R4 and R5, respectively. The fourth and fifth resistors R4 and R5 may have a function of detecting resistances of P polarity and N polarity, and the fifth and sixth relays 15 and 16 have a function of detecting voltages of P polarity and N polarity, respectively. can have Diodes 17a and 17b may be connected to each of the lines PL and NL to block current from flowing into the sensor module. In the presented drawing, I _s1 and I _s2 represent currents flowing through the first and second switches 11a and 11b, respectively. In addition, V _g , V _PV , V _LSP and V _LSN are the voltage between the neutral point of the sensor module and the ground, the voltage between the first and second lines (PL, NL) of the sensor module, P polarity and N polarity, respectively. indicates voltage.

Hereinafter, a process of detecting a failure of a solar cell module by a sensor module having such a structure will be described.

2A and 2B show an embodiment in which a single sensor module is applied to detecting a ground fault.

Referring to FIGS. 2A and 2B, for example, six solar cell modules 21_1 to 21_N may be connected in series, and each solar cell module 21_1 to 21_N may have the same or different voltages (V1 to V6). ) can be maintained. First and second lines may be respectively connected to positive and negative electrodes of the solar cell modules 21_1 to 21_N, and the sensor module described above may be connected to the first and second lines. The sensor module may be connected to the wire breaker 23, and a fuse may be connected to the wire breaker 23. The third relay 13 may be grounded by being connected to a grounding means 24 such as a bus bar. In the sensor module, the first and second resistors 25 and 26 connected to the first and second switches 11a and 11b may serve as ground fault current circuits and become shunt sensors. The resistor to which the third relay 13 is connected may have a function of detecting voltage by being connected to the neutral point of the sensor module. Specifically, the ground current is limited by the third resistor, and the ground voltage can be detected by the third relay 13 . The ground fault current of the N line and the P line can be detected by the first and second relays 12a and 12b, and the ground fault current of the N line and the P line is detected by the operation of the first and second switches 11a and 11b. It can be. As described above, resistors may be respectively connected to the first and second relays 12a and 12b, whereby the ground voltage of the P line or the N line may be detected. The first 2 switches 11a and 11b may control pulses of 2 ms or less, but are not limited thereto. Short-circuit failure can be detected by the fourth relay 14, and short-circuit failure can be detected by voltage detection. The voltage of the solar cell module 21 can be detected by the voltmeter 27 connected between the P and N lines, and the current of the solar cell module can be selectively measured by the ammeter. As shown in FIGS. 2A and 2B , fault points EF1 and EF2 may occur in the P or N line. When a failure occurs in the P pole line, as shown in FIG. 2A, the current flows from the anode P of the solar cell module 21 to the P pole fault point EF1, the third relay 13, and the second switch 12b. , flows along the N pole of the second relay 26 and the solar cell module 21. In the case of a ground fault, such a ground fault current circuit may be formed. When a failure occurs in the N pole line, as shown in FIG. 2B, current flows from the positive electrode of the solar cell module 21 to the first relay 12a, the first switch 11a, the third relay 13, and the grounding means. (24), the north pole fault point (EF2) and the negative electrode of the solar cell module (21). The N-pole fault point EF2 may be detected by the flow of current along the ground current circuit. A P or N pole failure point EF1 or EF2 may be respectively detected by the operation of the first or second switch 11a or 11b. The sensor module may be installed inside a junction box along with a wire breaker 23 or a fuse, but is not limited thereto, and may be installed in various locations to detect failure of wiring connecting the solar cell module 21. can

3A to 6B show an embodiment in which a multi-sensor module is applied to detecting a ground fault.

The sensor module may be a single sensor structure connected to each solar cell module or a multi-sensor structure connected to two or more solar cell modules. In the case of a multi-sensor module structure, current sensors LSI _P and LSI _N may be connected to the P line and the N line, respectively. The different sensor modules 10a and 10b connected to each of the solar cell modules 21a and 21b may be connected in parallel with each other, and an inverter or load 31 may be connected to one sensor module (eg 10a). . By operating the switches 11a to 11d installed in each sensor module, a ground fault or a similar fault occurring in a line connecting each of the solar cell modules 21a and 21b may be detected.

Referring to FIG. 3A , the first switch 11a of the first sensor module 10a may be in an operating state or a closed state, and the remaining switches 11b to 11d may be in an open state. If the fault point EP1 is formed on the P pole line of the first solar cell module 10a, each of the sensor modules 10a and 10b can be operated as follows, and the circuit shown in the lower right becomes an equivalent circuit. . Likewise in the case of FIGS. 3B to 6B , the circuit shown in the lower right represents an equivalent circuit.

First sensor module 10a: first switch 11a turned on

- The fault current trap loop becomes a high-resistance shunting circuit and no fault current flows.

-Load current flows from the first solar cell module 21a to LS1 _x (X is P or N) and differential current becomes DI = 0

- The 2nd and 3rd relays do not operate

Second sensor module (10b)

- Load current flows from the second solar cell module 21b to LS2 _x (X is P or N) and differential current becomes DI = 0

- Relays 2 and 3 do not operate.

Referring to FIG. 3B, a failure point may occur in the P pole line of the first solar cell module 21a, and the second switch 11b of the first sensor module 10a may be operated (ON), and thus In the same state, the first and second sensor modules 10a and 10b can be operated as follows.

First sensor module (10a)

- A small fault current flows according to (load 31 / (third resistor - second resistor))

-Load current flows from the first solar cell module 21a to LS1 _x (X is P or N) and differential current becomes DI = 0

- The 2nd relay is operated

Second sensor module (10b)

- Load current flows from the second solar cell module 21b to LS2 _x (X is P or N) and differential current becomes DI = 0

- The 1st and 2nd relays do not operate

As shown in FIG. 3B, current flows from the positive electrode of the first solar cell module 21a along the ground, the third relay, the second switch 11b, the second relay, and the negative electrode of the first solar cell module 21a. do.

Referring to FIG. 4A , the first switch 11c of the second sensor module 10b can be operated (ON), and the first fault point EF1 is on the P pole line of the first solar cell module 21a. When this occurs, the first and second sensor modules 10a and 10b may operate as follows.

First sensor module (10a)

-Load current flows from the first solar cell module 21a to LS1 _x (X is P or N) and differential current becomes DI = 0

- The 1st and 2nd relays do not operate

Second sensor module (10b)

- The fault current trap loop becomes a high-resistance shunt circuit and no fault current flows.

- Load current flows from the second solar cell module 21b to LS2 _x (X is P or N) and differential current becomes DI = 0

- The 1st and 2nd relays do not operate

Referring to FIG. 4B , when the second switch 11d of the second sensor module 10b connected to the second solar cell module 21b is operated (ON), the first and second sensor modules 10a and 10b have the following can work together.

First sensor module (10a)

- As the load current of the first solar cell module 10a flows through LS1 _P and the load current and fault current flow through LS1 _n , the fault current is detected as a differential current and DI≠0.

- The 1st and 2nd relays do not operate

Second sensor module (10b)

- Fault current flows through the P pole line of the first solar cell module 10a as a fault current trap loop

- The load current of the second solar cell module 21b and the fault current of the first solar cell module 21a flow through SL2 _p , the load current of the first solar cell module 21b flows through LS2 _n , and failure due to differential current As current is detected, DI≠0 becomes

- The 1st relay is operated

Dotted lines in FIG. 4B represent the flow of load current or fault current from each of the solar current modules 21a and 21b.

Referring to FIG. 5A , when a second fault point EF2 may occur in the N-pole line of the first solar cell module 21a and the first switch 11a of the first sensor module 10a is operated (ON), the first and second sensor modules 10a and 10b may operate as follows.

First sensor module (10a)

- Fault current flows according to (load 31 / third resistor - first resistor)

-Load current flows from the first solar cell module 21a to LS1 _x (X is P or N) and differential current becomes DI = 0

- The 1st relay is operated

Second sensor module (10b)

- Load current flows from the second solar cell module 21b to LS2 _x (X is P or N) and differential current becomes DI = 0

- Relay 1 and 2 do not operate.

Referring to FIG. 5B , when a second fault point EF2 may occur in the N pole line of the first solar cell module 21a and the second switch 11b of the first sensor module 10a is operated. (ON), the first and second sensor modules 10a and 10b may operate as follows.

First sensor module (10a)

- The fault current loop trap becomes a high-resistance shunt circuit and no fault current flows.

-Load current flows from the first solar cell module 21a to LS1 _x (X is P or N) and differential current becomes DI = 0

- The 1st and 2nd relays do not operate

Second sensor module (10b)

- Load current flows from the second solar cell module 21b to LS2 _x (X is P or N) and differential current becomes DI = 0

- The 1st and 2nd relays do not operate

Referring to FIG. 6A , when a second fault point EF2 may occur in the N pole line of the first solar cell module 21a and the first switch 11c of the second sensor module 10a is operated. (ON), the first and second sensor modules 10a and 10b may operate as follows.

First sensor module (10a)

-Load current flows from the first solar cell module 21a to LS1 _x (X is P or N) and differential current becomes DI = 0

- The 1st and 2nd relays do not operate

2nd sensor module

- The fault current loop trap becomes a high-resistance shunt circuit and no fault current flows.

- Load current flows from the second solar cell module 21b to LS2 _x (X is P or N) and differential current becomes DI = 0

- Relay 1 and 2 do not operate.

Referring to FIG. 6B , when a second fault point EF2 may occur in the N-pole line of the first solar cell module 21a and the second switch 11d of the second sensor module 10a is operated. (ON), the first and second sensor modules 10a and 10b may operate as follows.

First sensor module (10a)

-Load current flows from the first solar cell module 21a to LS1 _x (X is P or N) and differential current becomes DI = 0

- The 1st and 2nd relays do not operate

Second sensor module (10b)

- The fault current loop trap becomes a high-resistance shunt circuit and no fault current flows.

- Load current flows from the second solar cell module 21b to LS2 _x (X is P or N) and differential current becomes DI = 0

- The 2nd relay does not operate.

In the embodiments shown in FIGS. 3A to 6B , dotted lines represent current flows from the first and second solar cell modules 21a and 21b to the first and second sensor modules 10a and 10b or the load 31 . As can be seen from the presented embodiment, the first to second sensor modules 10a and 10b in which the fault points EF1 and EF2 are generated in the P pole or N pole line of the first solar cell module 10a. 2 Switches 11a to 11d are operated to detect the flow of current to confirm the failure state. When each of the switches 11a to 11d where a fault point occurs in the P pole or N pole line of the second solar cell module 10b is operated, the current flowing along the first and second sensor modules 10a and 10b is detected and the fault occurs. status can be checked. The multi-sensor module structure can be made in various forms and is not limited to the presented embodiments.

7 illustrates an embodiment of a failure detection process by a sensor module according to the present invention.

Referring to FIG. 7, a method for detecting a fault condition occurring in a P pole line or an N pole line of a solar cell module by a sensor module formed by electrically connecting a plurality of relays is at least one relay connected to at least one relay. Operating the switch to monitor the current flow through the sensor module (P71); Checking whether at least one relay for ground fault detection is operated (P72); Checking whether a difference value is generated between the current flowing through the P pole line and the N pole line of the solar cell module (P74); and determining that a failure has occurred in the P pole line or the N pole line (P76).

The sensor module may be installed between the solar cell module and the inverter, and may be installed inside a junction box, for example. Each sensor module can be connected to each solar cell module, and the sensor modules can be operated in a single mode or in multiple modes. Two switches may be disposed in the sensor module, and each switch may be operated to detect a current flowing through the relay or a voltage of the relay to determine whether the P-pole line or the N-pole line is out of order. When the first or second switch is turned on (P71), it is confirmed whether current is detected from the switch and the P pole line, the switch and the N pole line, the P pole line and the N pole line, or the relay connected to the neutral point. can If no current is detected in each relay, it is determined that no failure occurs (N), and thus no alarm is generated (P73). In contrast, when a current is detected in a ground relay such as detection of a ground fault current (Y), a difference in current flowing between the P pole line and the N pole line can be confirmed (P74). If there is no current difference (N), no alarm is generated (P75), whereas if a current difference is detected (Y), it is determined that a fault has occurred in the P pole line or the N pole line (P76), and an alarm may occur (P77).

A number of relays can be connected together in a variety of ways for detection of a fault condition such as, for example, a ground fault, without limiting the present invention by this.

Although the present invention has been described in detail with reference to the presented embodiments above, those skilled in the art will be able to make various modifications and variations without departing from the technical spirit of the present invention with reference to the presented embodiments. . The present invention is not limited by these variations and modifications, but is limited only by the claims appended below.

11a, 11b: switch 12a, 12b: relay
14: relay 15, 15: relay
17a, 17b: Diodes 21_1 to 21_N: Solar cell module

Claims (5)

first and second switches 11a and 11b installed between the first and second lines PL and NL electrically connected to each other;
first and second relays 12a and 12b electrically connecting the first and second switches 11a and 11b and the first and second lines PL and NL;
A third relay 13 connected between the first and second switches 11a and 11b;
A fourth relay 14 electrically connecting the first and second lines PL and NL; and
Including fifth and sixth relays 15 and 16 connected to the first and second lines PL and NL, respectively,
A first relay 12a is connected between the first switch 11a and the first line PL, a first resistor R1 is connected in series with the first relay 12a, and a second switch 11b and A second relay 12b is connected between the two lines NL, and the second relay 12b and the second line NL are connected in series by a second resistor R2,
One end of the third relay 13 is grounded and a third resistor R3 is connected in parallel with the third relay 13,
The fourth and fifth resistors R4 and R5 are connected to the contacts of the fourth relay 14 and the first and second lines PL and NL, respectively, and a fifth resistor is connected to each of the fourth and fifth resistors R4 and R5. , 6 relays (15, 16) are connected in parallel, characterized in that the sensor module for fault detection of the DC line connected to the solar cell module array. delete delete delete The sensor module according to claim 1, wherein the first and second lines (PL, NL) connect between the solar cell module and the inverter.

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