KR20220095712A - Energy management system having data protection function - Google Patents

Abstract

According to the present invention, an energy management system with a data protection function may adjust an encoding step or determine whether to encode according to a level of noise when data is transmitted between an energy management unit and a battery management unit. Accordingly, during data transmission between the energy management unit and the battery management unit, data may be protected and transmission speed may be increased. The present invention can be applied not only to the battery management unit, but also to all types of management objects, such as single or multiple power devices and connection boards capable of exchanging data with the energy management unit.

Description

Energy management system having data protection function

The present invention relates to an energy management system with a data protection function.

In general, an energy management system is a system that manages a single or a plurality of power devices, a battery management unit, a connection panel, etc. (hereinafter referred to as “management target”) for optimal operation of power consumption facilities. Information is exchanged through wired communication lines.

The RS485 serial communication method is widely used for wired communication to transmit necessary information between the energy management system and the management target.

Compared to the parallel communication method, the RS485 serial communication method has a lower transmission speed but a much longer communication distance, and the cost is low because the existing communication line (telephone line, etc.) can be easily used. In addition, since it is a half-duplex communication method, transmission and reception cannot be performed at the same time, but transmission and reception are possible, and the maximum reach distance is 1.2km, which has the advantage of a long data transmission distance.

In addition, as a communication method with enhanced input and output voltages, network creation (multi drop) of multiple devices is possible, and excellent performance is achieved in an environment where communication with devices distributed in multiple networks is required using noise and multiple devices. have

In addition, using two RS-485, but using an insulation IC between RS-485 to restore the data attenuated in the transmission process through RS-485 of the front stage connected to the energy management system, and through RS-485 of the rear stage Data can be transmitted to the managed device.

However, despite the excellent RS485 serial communication method, if data is transmitted without encoding to increase the data transmission speed between the energy management system and the management target, it is difficult to restore data when noise occurs, and on the contrary, it is encoded to a level that can be restored to any form of noise. Therefore, there is a problem in that the transmission speed becomes slow when transmitting.

Korean Patent Publication (10-2013-0137975)

It is an object of the present invention to provide an energy management system having a data protection function that can solve the above problems.

An energy management system with a data protection function according to the present invention,

an energy management unit that optimally manages the operation of power generation facilities through information collection and monitoring in order to efficiently use the energy of the entire connected power supply and supply system;

a battery management unit in which one or more batteries for supplying power to one or more power consuming devices are mounted on the basis of the information received from the energy management unit, and monitoring the state of the batteries to maintain and manage the batteries in an optimal state;

With respect to the information transmitted from the energy management unit, the battery management unit detects a response signal that is normally received,

If the response signal is detected, the information transmitted by the energy management unit is not encoded,

a transmission unit that, if the response signal is not detected, performs encoding on the information transmitted by the energy management unit until the response signal is detected by adding additional information (redundancy) according to a noise inflow state of a communication line; and

When the transmission unit encodes the information transmitted from the energy management unit, it receives the encoded transmission information and decodes it by forward error correction even if it is damaged within 10 bytes by noise and transmits it to the battery management unit,

and a receiver for receiving the unencoded transmission information and transmitting the unencoded information to the battery manager as it is when the transmitter does not encode the information transmitted from the energy management unit.

The energy management system having a data protection function according to the present invention may adjust the encoding step or determine whether to encode according to the noise level when data is transmitted between the energy management unit and the battery management unit. Accordingly, when data is transmitted between the energy management unit and the battery management unit, data can be protected and a transmission speed can be increased.

The present invention can be applied not only to the battery management unit, but also to all types of management objects, such as single or multiple power devices and connection panels, that can exchange data with the energy management unit.

1 is a schematic diagram of an energy management system having a data protection function according to an embodiment of the present invention.
2 is a detailed view (A) of the transmitter and a detailed view (B) of the receiver shown in FIG. 1 .

Hereinafter, an energy management system having a data protection function according to an embodiment of the present invention will be described in detail. Reference is made basically to FIGS. 1 and 2 .

The energy management system 100 with a data protection function according to an embodiment of the present invention includes an energy management unit 110 , a transmission unit 120 , a reception unit 130 , and a battery management unit 140 .

[Energy Management Department]

The energy management unit 110 collects information in order to efficiently use the energy of the entire power supply and supply system connected thereto, and optimally manages the operation of the power generation facility through monitoring.

[Transmission part]

The transmission unit 120 is

Detects a "response signal to the information transmitted by the energy management unit 110 that the battery management unit 140 normally receives" (hereinafter abbreviated as "response signal"),

Encoding is performed on "information transmitted by the energy management unit 110 according to the detection result" (hereinafter, abbreviated as "transmission information").

The transmission unit 120 includes a transmission control unit 121 , a first RS-485 122 , a first insulation IC 123 , and a second RS-485 124 .

When a response signal is detected

When the transmission control unit 121 detects the response signal, the transmission information is not encoded, and transmission information is transmitted through the first RS-485 (122), the first insulation IC (123), and the second RS-485 (124). It is transmitted to the receiver 130 .

When no response signal is detected

When the transmission control unit 121 does not detect the response signal, until the response signal is detected, the transmission information is received from the first RS-485 122 and encoded in stages without going through the first insulating IC 123 . , and transmits the encoded transmission information to the receiving unit 130 through the second RS-485 (124). In this case, the encoding is performed by adding additional information (redundancy) according to the noise inflow state of the communication line. Redundancy is a redundant bit for error control.

For example, when the transmission control unit 121 does not detect a response signal, first-step encoding with the lowest encoding strength is performed on the transmission information. Here, even if the transmission information is damaged within 10 bytes due to noise, the first-step encoding has a strength enough to be decoded by forward error correction.

When a response signal is not detected even after the first-step encoding is performed, the second-step encoding, which is stronger than the first-step encoding, is performed on the transmission information.

When no response signal is detected even after the second-step encoding is performed, the third-step encoding is finally performed on the transmission information. The 3-step encoding has the highest level of encoding strength that can transmit transmission information without being affected by noise.

For this step-by-step encoding, the transmission control unit 121 encodes transmission information using a Reed-Solomon code (R-S code).

The Reed-Solomon code is a kind of non-binary BCH code that can correct errors in the cluster type proposed by Reed and Solomon.

Reed-Solomon code indicates that when the input is 188 bytes, the error of 8 bytes is perfectly corrected if 16 bytes are appended and transmitted.

The Reed-Solomon code uses the characteristic of excellent cluster error correction and has excellent correcting ability for sporadic errors. Channel errors are strongly eliminated by using it for space communication, satellite communication, and satellite broadcasting, which are environments that

In the case of using the Reed-Solomon code, transmission information can be protected from noise, but the receiving unit 130 decodes the transmission information encoded with the Reed-Solomon code and the battery management unit 140 can use it normally. However, it takes a lot of time for the receiver 130 to decode the transmission information encoded with the Reed-Solomon code.

In order to shorten this time, when the response signal is detected, the transmission control unit 121 does not encode transmission information, and the first RS-485 122, the first insulation IC 123, and the second RS-485 Transmission information is transmitted to the receiving unit 130 through 124 .

Then, the reception control unit 131 directly transmits the unencoded transmission information to the battery management unit 140 through the third RS-485 (132), the second insulation IC (133), and the fourth RS-485 (134). . Accordingly, the battery management unit 140 can use the transmission information sent from the transmission control unit 121 to the reception control unit 131 quickly.

[receiver]

The receiving unit 130 includes a receiving control unit 131 , a third RS-485 132 , a second insulating IC 133 , and a fourth RS-485 134 .

When transmission information is encoded

The reception control unit 131 receives the transmission information encoded according to the encoding step performed by the transmission control unit 121 through the third RS-485 132 and decodes it by forward error correction even if it is damaged within 10 bytes by noise, It is transmitted to the battery management unit 140 through the fourth RS-485 134 without going through the second insulating IC 133 .

In case the transmission information is not encoded

The reception control unit 131 directly transmits the unencoded transmission information to the battery management unit 140 through the third RS-485 132 , the second insulation IC 133 , and the fourth RS-485 134 .

[Battery Management Department]

The battery management unit 140, based on the information received from the energy management unit 11, is equipped with one or more batteries that supply power to one or more power consuming devices, and monitors the state of the batteries to maintain and manage the batteries in an optimal state. do.

The Battery Management System (BMS, 140) monitors the voltage, current, and temperature of the battery pack and maintains it in an optimal state, predicting when to replace the battery and detecting battery problems in advance. manage

Hereinafter, an energy management system having a data protection function according to another embodiment of the present invention will be described.

The configuration of an energy management system with a data protection function according to another embodiment of the present invention is the same as that of the energy management system with a data protection function according to an embodiment. However, the way it works is different.

An embodiment of the present invention gradually strengthens the coding strength of transmission information step by step when no response signal is detected, but in another embodiment of the present invention, transmission information is encoded with the highest strength from the beginning, and the response signal is detected. In this case, the coding strength is gradually lowered step by step.

To this end, the transmission control unit 121 lowers the encoding level of transmission information until it cannot detect a response signal, and when a response signal is not detected at a certain stage, the transmission information is transmitted at a level higher than that of that stage. encode

At this time, the transmission control unit 121 receives and encodes the transmission information from the first RS-485 (122), without going through the first insulating IC (123), the transmission information encoded through the second RS-485 (124) is transmitted to the receiver 130 .

The receiver 130 receives the encoded transmission information, decodes it, and transmits it to the battery manager 140 . To this end, the reception control unit 131 receives the encoded transmission information from the third RS-485 132 and decodes it by forward error correction even if it is damaged within 10 bytes by noise, without going through the second insulating IC 133 . , transmits the decoded transmission information to the battery management unit 140 through the fourth RS-485 (134).

On the other hand, since the transmission control unit 121 lowers the encoding strength, when a response signal is detected even when transmission information is not encoded at all, the first RS-485 122, the first insulation IC 123, and the second RS Transmission information is transmitted to the receiving unit 130 through -485 (124), and the receiving control unit 131 transmits unencoded transmission information to the third RS-485 (132), the second insulation IC (133), and the fourth RS It is transmitted to the battery management unit 140 through -485 (134).

110: energy management unit 120: transmission unit
121: transmission control unit 122: first RS-485
123: first insulation IC 124: second RS-485
130: receiving unit 131: receiving control unit
132: the third RS-485 133: the second insulation IC
134: fourth RS-485 140: battery management unit

Claims (5)

an energy management unit that optimally manages the operation of power generation facilities through information collection and monitoring in order to efficiently use the energy of the entire connected power supply and supply system;
a battery manager in which one or more batteries for supplying power to one or more power consuming devices are mounted on the basis of the information received from the energy manager, and to monitor the state of the batteries to maintain and manage the batteries in an optimal state;
With respect to the information transmitted from the energy management unit, the battery management unit detects a response signal that is normally received,
If the response signal is detected, the information transmitted by the energy management unit is not encoded,
a transmission unit that, when the response signal is not detected, performs encoding on the information transmitted by the energy management unit until the response signal is detected by adding additional information (redundancy) according to a noise inflow state of a communication line; and
When the transmission unit encodes the information transmitted from the energy management unit, it receives the encoded transmission information and decodes it by forward error correction even if it is damaged within 10 bytes by noise and transmits it to the battery management unit,
and a receiving unit for receiving unencoded transmission information and transmitting the unencoded information to the battery management unit as it is when the transmitting unit does not encode the information transmitted from the energy management unit. The method of claim 1,
The transmission unit includes a transmission control unit, a first RS-485, a first insulation IC, and a second RS-485, and the receiving unit includes a reception control unit, a third RS-485, a second insulation IC and a fourth RS-485 and
When the transmission control unit detects the response signal of the battery management unit, the transmission information is not encoded by the energy management unit, and the transmission information is transmitted through the first RS-485, the first insulation IC, and the second RS-485. control to transmit to the receiver,
The reception control unit has a data protection function, characterized in that the uncoded transmission information is transmitted to the battery management unit through the third RS-485, the second insulation IC and the fourth RS-485 One energy management system. The method of claim 1,
The transmission unit includes a transmission control unit, a first RS-485, a first insulation IC, and a second RS-485, and the receiving unit includes a reception control unit, a third RS-485, a second insulation IC and a fourth RS-485 and
When the transmission control unit does not detect the response signal of the battery management unit, it receives the transmission information of the energy management unit from the first RS-485 and encodes it in stages until the response signal is detected, so that the first insulation IC Transmitting the encoded transmission information to the receiving unit through the second RS-485 without going through,
The reception control unit receives and decodes the encoded transmission information from the third RS-485 according to the encoding step performed by the transmission control unit, and through the fourth RS-485 without going through the second insulating IC An energy management system with a data protection function, characterized in that it is transmitted to the battery management unit. 4. The method of claim 3,
When the transmission control unit does not detect the response signal,
First-step encoding with the lowest encoding strength is performed,
If the response signal is not detected even when the first-step encoding is performed, a two-step encoding having a higher intensity than that of the first-step encoding is performed;
Energy management system with a data protection function, characterized in that when the response signal is not detected even when the two-step encoding is performed, a three-step encoding having a higher intensity than the two-step encoding is performed. 5. The method of claim 4,
The energy management system with a data protection function, characterized in that the three-step encoding has the highest encoding strength capable of transmitting the transmission information to the battery management unit without being affected by noise.

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