KR102045297B1 - Energy management system for environmental Infra structure using ESS - Google Patents

Abstract

The present invention relates to an energy management system for environmental foundation facilities using an energy storage system (ESS). The energy management system for environmental foundation facilities using an ESS comprises: an energy generation unit generating new renewable energy; an ESS unit processing and storing electric energy generated from the energy generation unit; environmental foundation facilities receiving the electric energy from the ESS unit; and an EMS unit monitoring and controlling state information of the ESS unit and the electric energy supplied to the environmental foundation facilities.

Description

Energy management system for environmental infrastructure using ESS

The present invention relates to an energy management system for efficiently supplying renewable energy to an environmental foundation such as a sewage treatment plant using an energy storage system (ESS).

In recent years, natural disasters all over the world are suffering from abnormal climate phenomenon caused by global warming. This is due to the release of carbon dioxide from the use of fossil fuels, and efforts are being made to reduce carbon dioxide emissions worldwide.

However, as the industry develops and civilization develops, the amount of energy consumed by mankind increases exponentially. Therefore, the demand and utilization of infinitely clean alternative energy is increasing. Among these alternative energy, the photovoltaic power generation system using solar energy is an energy that can be supplied almost indefinitely, and thus the use of solar power is increasing worldwide.

On the other hand, ESS (Energy storage system) generally refers to a storage device that stores over-produced power or irregularly generated renewable energy in a power plant and transmits electricity when power is temporarily lacked. Specifically, ESS refers to a system that stores electricity in an electric power system to supply energy when and where it is needed.

Recently, the importance of ESS has emerged as an essential device for storing unstable generation energy during photovoltaic power generation, a rapidly growing renewable energy source, and stably supplying it again to the power system when needed. If there is no ESS, unstable power supply depending on wind or solar can cause serious problems such as sudden power failure in the power system.

Republic of Korea Patent No.1859939

The present invention has been made to solve the above problems, and provides an energy management system for efficiently supplying renewable energy to environmental foundations such as sewage treatment plants using ESS, while automatically monitoring the abnormality of such a system To provide a system that can be done.

As a means for solving the above problems, the environmental infrastructure energy management system using the ESS of the present invention (hereinafter referred to as the "system of the present invention"), the energy generation unit for producing renewable energy; An ESS unit for processing and storing electrical energy produced from the energy generating unit; An environmental foundation facility receiving electrical energy from the ESS unit; And an EMS unit for monitoring and controlling the state information of the ESS unit and the electric energy supplied to the environmental base facility.

As an example, the state information may include data on the presence or absence of an abnormality in a specific location of the ESS unit.

As an example, the ESS unit includes a diagnostic unit for diagnosing the state information. The diagnostic unit includes a resistance value measuring sensor configured at a plurality of specific locations and a resistance value measured at the specific location measured by the resistance value measuring sensor as an EMS unit. A communication unit for transmitting is included, and the EMS unit includes an analysis unit for analyzing the presence or absence of abnormality of a specific location based on the resistance value of the specific location received by the communication unit.

As an example, the analysis unit stores the reference resistance value of a specific location and sets it as a reference value to be compared and compares the resistance value measured by the resistance measurement sensor to analyze whether there is an abnormality of the specific location. .

As an example, a protective coating layer is coated on the outer circumference of the resistance measurement sensor, and the protective coating layer is 10 to 20 parts by weight of carbon graphite powder, 5 to 10 parts by weight of butyl rubber, and 0.5 to 1 boron nitride based on 100 parts by weight of the resin. By weight, characterized in that it comprises 0.5 to 1 parts by weight of carbon fiber.

As described above, the system of the present invention has an advantage of enabling efficient energy management by storing energy generated from renewable energy such as solar light and supplying it to an environmental foundation such as a sewage treatment plant.

In addition, the system of the present invention has the advantage that the immediate action can be easily by accurately monitoring the presence of abnormalities such as deterioration of a specific place that may occur in the ESS unit.

1 is a block diagram illustrating a system of the present invention.
2 is a block diagram showing a detailed configuration of an ESS unit which is one configuration of the present invention.
3 is a block diagram showing the detailed configuration of the diagnostic unit shown in FIG.
Figure 4 is a block diagram showing the detailed configuration of the EMS unit of one configuration of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, the term or word used in the present specification and claims is based on the principle that the inventor can appropriately define the concept of the term in order to best describe the invention of his or her own. It should be interpreted as meanings and concepts corresponding to the technical idea of

The system 1 of the present invention includes an energy generator 2 for producing renewable energy as shown in FIG. 1; An ESS unit (3) for processing and storing electrical energy produced from the energy generating unit (2); An environmental foundation (4) receiving electrical energy from the ESS unit (3); And an EMS unit 5 for monitoring and controlling the state information of the ESS unit 3 and the electric energy supplied to the environmental foundation 4.

The energy generator 2 corresponds to a configuration for producing renewable energy, for example, the energy generator 2 may be configured to produce solar energy by photovoltaic power generation. In addition, it is natural that the energy generator 2 may perform solar energy and wind energy at the same time, so that energy can be complementarily produced.

The ESS unit 3 corresponds to a configuration for processing and storing the electrical energy produced from the energy generating unit (2).

As shown in FIG. 2, the ESS unit 3 may include a battery 31, a power converter 32, a PCS unit 33, and a diagnosis unit 34. That is, the electrical energy is stored in the battery 31, but the electrical energy is processed by the power conversion unit 32, the PCS unit 33, etc., and the abnormality of the ESS unit 3 is determined by the diagnostic unit 34. To be detected.

The power converter 32 corresponds to a configuration for converting and outputting electrical energy produced by the energy generator 2 to AC power. The power conversion unit 32 may be configured to include a plurality of switching elements and system-linked filter in a known configuration. For example, the plurality of switching elements converts the DC voltage into an AC voltage through switching of an on or off state based on a PWM signal for controlling the power converter 32. Corresponds to the configuration.

The PCS unit 33 corresponds to a configuration of converting AC power by the power converter 32 into DC power and storing the AC power in the battery 31. In addition, the PCS unit 33 converts the DC power stored in the battery 31 into AC power to supply the environmental foundation 4.

The diagnostic section 34 diagnoses the status information of the ESS section 3, and the status information includes data on the presence or absence of an abnormality at a specific location of the ESS section 3.

Herein, the specific location may define a detailed configuration such as the battery 31, the power conversion unit 32, and the PCS unit 33 constituting the ESS unit 3, and in addition, various electrical components included in each detailed configuration. You can define the device.

In addition, abnormality is defined as various abnormalities such as deterioration and fire that may occur in a specific place. When such an abnormality occurs, the failure of the entire ESS part 3 as well as the failure of the system 1 as a whole, The diagnostic unit 34 is intended to diagnose the presence or absence of abnormalities of these specific places.

To this end, the diagnostic unit 34 transmits the resistance value measuring sensor 341 and the resistance value measured at the specific location measured by the resistance value measuring sensor 341 to the EMS unit 5. 342 may be included. In connection with this, the EMS unit 5 may include an analysis unit 51 for analyzing the presence or absence of abnormality of a specific location based on the resistance value of the specific location received from the communication unit 342.

That is, the diagnosis unit 34 includes a resistance value measuring sensor 341 configured at a specific location of the ESS unit 3, and the resistance value of the specific location measured by the resistance value measuring sensor 341 is the communication unit 342. And the analysis unit 51 of the EMS unit 5 analyzes the presence or absence of abnormality of a specific location based on the resistance value of the specific location received from the communication unit 342. will be.

For example, the analysis unit 51 stores a reference resistance value of a specific location and sets it as a comparison target reference value to compare the resistance value measured by the resistance measurement sensor 341 to analyze whether there is an abnormality of the specific location. Will be.

As described above, in analyzing the abnormality of a specific location in the analysis unit 51, it is important to derive the accurate resistance value of a specific location. In the case where fatigue accumulation and static electricity are generated due to the continuous impact on the resistance measurement sensor 341, In this case, the resistance value may be changed by various causes such as when the pollutant is deposited. The present invention provides an embodiment for solving such a problem.

In the present embodiment, a protective coating layer is applied to the outer periphery of the resistance measurement sensor 341, the protective coating layer is 10 to 20 parts by weight of carbon graphite powder, 5 to 10 parts by weight of butyl rubber, boron Nitride 0.5 to 1 parts by weight, characterized in that it comprises 0.5 to 1 parts by weight of carbon fiber.

The resin is not limited to a kind thereof, but a urethane resin may be applied, and the urethane resin may be excellent in elasticity to improve resistance from external impact of the sensor.

The carbon graphite is for reinforcing the strength of the protective coating layer and to improve the impact resistance against external impacts, and control the generation of static electricity by adding carbon graphite, a conductor, so that leakage current is generated by static electricity or foreign matter is formed on the surface. It is to prevent deposition. When leakage current is generated and when foreign matter accumulates on the surface, it acts as a factor that hinders the accuracy of sensing, so that carbon graphite is added to the protective coating layer.

In addition, butyl rubber is added in addition to the carbon graphite. The butyl rubber is a rubber obtained by ion-polymerizing isobutylene and a small amount of isoprene in a liquid state at a low temperature, and is 1.5 to 4.5% in isobutylene having a purity of 99% or more. Add isoprene mixture and pure methyl chloride, add anhydrous aluminum chloride as a catalyst, and then put it in a polymerization reactor to polymerize at a low temperature of about -100 ℃. It is divided into several kinds such as Ren. The butyl rubber absorbs shocks and is particularly flexible at low temperatures such as -50 ° C. because the elastomer does not crystallize well even at low temperatures.

The reason why the butyl rubber is added is not only to strengthen the impact resistance but also to the expansion and contraction of the paste in the course of repeated freezing and melting in the winter due to the material properties that do not lose elasticity at low temperatures as mentioned above. The impact on the butyl rubber is to be alleviated to improve the cold resistance.

That is, if the freeze-thawing is repeated in the paste at low temperatures, cracks may occur in the paste due to repeated stretching and contraction.But the butyl rubber can maintain elasticity even at low temperatures, thereby compensating for such stretching. The above can be controlled.

In addition, the carbon graphite may have a slight contribution to improving the impact resistance of the paste at a low temperature, and this is supplemented by butyl rubber to maintain impact resistance even at low temperature by the addition of butyl rubber. That is, by the addition of butyl rubber, the protective coating layer can improve the impact resistance even in a low temperature environment such as winter, so that the shock can be transmitted to the sensor.

Meanwhile, the protective coating layer functions as an insulating barrier layer, and hydrogen atoms in the protective coating layer penetrate into the sensor, causing a change in capacity characteristics. The change in the capacity characteristic of course prevents the derivation of the accurate sensing value, and thus the present invention allows boron nitride to be added to the protective coating layer.

In the bonding surface of the protective coating layer in contact with the resistance measuring sensor 341, voids are generated. These voids react with alkali and metal components of the surface layer to generate hydrogen gas, and when the hydrogen employment ability is supersaturated, hydrogen is cured in the curing process. This is due to the formation of voids, cracks, etc. on the surface of the paste as it is released to the outside of the paste structure. That is, as mentioned above, the hydrogen atom penetrates into the sensor by the release of hydrogen, causing a change in capacity characteristics.

The boron nitride is to be added to the protective coating layer to fix hydrogen by boron nitride to fix the hydrogen by boron nitride to solve the problem of hydrogen penetration by the above-mentioned sensor.

The carbon fiber is to control the micro-crack, such as the protective coating layer can be generated during the curing process by cross-linking action to prevent the impact resistance degradation due to the crack of the protective coating layer, the foreign matter is deposited in the micro-cracks deposition of these foreign matters Corrosion may cause the disturbance of the sensing value, so that the carbon coating is further added to the protective coating layer.

In addition, the carbon fiber is a conductor to control the generation of static electricity in the same way as the carbon graphite to prevent the leakage current caused by the static electricity or foreign matter deposited on the surface.

The environmental foundation 4 is configured to receive electrical energy from the ESS unit 3, and the environmental foundation 4 is a concept that includes a sewage treatment plant, which is required for various equipment of the environmental foundation 4. The energy is to be supplied from the ESS unit (3).

The EMS unit 5 corresponds to a configuration for monitoring and controlling the state information of the ESS unit 3 and the electric energy supplied to the environmental foundation 4.

Monitoring and controlling the status information of the ESS unit 3, as mentioned above, the EMS unit 5 is based on the resistance value of the specific place received from the ESS unit 3 to determine whether there is an abnormality of the specific place. The analysis unit 51 to be analyzed is included. The analysis unit 51 stores a reference resistance value of a specific location and sets it as a reference value to be compared with the resistance value measured by the resistance measurement sensor 341. By comparing, it is to analyze the presence or absence of the abnormality of the specific place.

That is, as shown in FIG. 4, the EMS unit 5 determines whether there is an abnormality in a specific location of the ESS unit 3 in the analysis unit 51, and the control unit 52 that receives the result of the abnormality has received the ESS unit. To control (3).

For example, if an abnormality is recognized at a specific location of the ESS unit 3, the controller 52 controls the PCS unit 33 of the ESS unit 3 to shut down the entire ESS unit 3 to prevent further damage and to immediately As a result, maintenance and repair of specific places are to be made. Since the control of the controller 52 may be implemented in various ways, a detailed description thereof will be omitted.

In addition, the EMS unit 5 monitors and controls the electric energy supplied to the environmental foundation 4, for example, by monitoring the amount of energy supplied from the ESS unit 3 to the environmental foundation 4. When it is excessive or insufficient, it is possible to control the amount of energy supplied in this case. In this case, since the monitoring and control of the electric energy supplied to the environmental foundation 4 may be configured in various ways, the detailed description thereof will be omitted.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1: System of the ear disease 2: Energy generator
3: ESS part 4: Environment basic facility
5: EMS

Claims (5)

An energy generator for producing renewable energy;
An ESS unit for processing and storing electrical energy produced from the energy generating unit;
An environmental foundation facility receiving electrical energy from the ESS unit; And
And an EMS unit for monitoring and controlling the state information of the ESS unit and the electric energy supplied to the environmental foundation.
The state information includes data on the presence or absence of abnormality in a specific place of the ESS unit,
The ESS unit includes a diagnostic unit for diagnosing the state information, and the diagnostic unit transmits a resistance value measuring sensor configured at a plurality of specific locations and a resistance value measured at the specific location measured by the resistance value measuring sensor to the EMS unit. Is included, an analysis unit for analyzing the presence or absence of the abnormality of the specific location based on the resistance value of the specific location received by the communication unit,
The analysis unit stores a reference resistance value of a specific location and sets it as a reference value to be compared and compares the resistance value measured by the resistance value measuring sensor to analyze whether there is an abnormality of the specific location,
On the outer periphery of the resistance measurement sensor is coated with a protective coating layer containing 0.5 to 1 parts by weight of carbon fiber relative to 100 parts by weight of resin,
The protective coating layer includes 10 to 20 parts by weight of carbon graphite powder for improving impact resistance and controlling static electricity generation, 5 to 10 parts by weight of butyl rubber for improving cold resistance, and hydrogen atoms penetrating into the sensor. Environmental foundation energy management system using ESS characterized in that it further comprises 0.5 to 1 parts by weight of boron nitride for controlling the. delete delete delete delete

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