KR101550875B1 - Active type energy storage system - Google Patents

Abstract

The present invention relates to an active ESS, comprising: a grid-connected power generation source; An independent development party; An auxiliary power supply; A load; Power Conditioning System (PCS), which is connected to grid-connected power generation source, independent power generation source and load, respectively, and which converts one of the first and second power sources to peak auxiliary power, The auxiliary power supply unit includes a battery connected to the power line connected to the PCS and outputting the power to the first auxiliary power source, a super power source connected in parallel with the battery to charge and discharge the first auxiliary power, A capacitor, and a DC-DC converter for step-up by applying a second auxiliary power to output a peak auxiliary power.

Description

Active type energy storage system

In particular, the present invention relates to an active ESS, and more particularly, to an active ESS, in which a supercapacitor is connected in parallel to a battery connected to a PCS (Power Conditioning System) that converts DC power to AC power and transfers the DC power to a load, To an ESS capable of actively compensating a power applied to a PCS.

The ESS (Energy Storage System) is used to stably connect the power generated from renewable energy to the power system. New and renewable energy has the disadvantage that the electric power production stability is poor due to the electric energy generated by solar power or wind power generation. To overcome these drawbacks, renewable energy is used in combination with ESS. The ESS stores excess power generated by the battery using Li-Ion Battery (LIB), and discharges when there is insufficient power to stabilize power supply and demand. In other words, the ESS improves the efficiency of power utilization by accumulating and storing new renewable energy that is gathered when power demand is low, and then using the power stored in the peak time period with high power demand.

ESS is applied to stand-alone power generation system which operates only by itself like solar power generation, grid power generation system which operates in conjunction with solar power generation system and commercial power system through the above-mentioned advantages, and in order to apply it stably, ESS A technique for predicting the lifetime of a battery applied to a battery is developed.

Korean Patent Laid-Open Publication No. 2012-0134415 (Patent Document 1) relates to a battery life predicting system of an ESS and includes a pack voltage calculation processor, a state of health (SOH) determination processor, an SOH calculation processor, and a SOC correction processor . The pack voltage calculation processor receives the cell voltage of the battery cell of the ESS and calculates the pack voltage of the battery pack. The SOH determination processor receives the pack voltage and sets the preconditions for determining the SOH, do. When determining the SOH, the SOH calculation processor checks the pack voltage at that time when the precondition is satisfied, and calculates the SOH using the voltage difference between the current pack voltage and the initial pack voltage. The SOC correction processor multiplies the SOH by the initial rated capacity to calculate the state of charge (SOC) correction capacity.

The conventional ESS to which the battery life predicting system such as Patent Document 1 is applied can not compensate for the change of the peak in a very short time due to the long discharge time of the battery by applying only the battery to the ESS, have.

Patent Document 1: Korean Laid-open Patent No. 2012-0134415 (Registered on December 12, 2012)

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for connecting a supercapacitor in parallel to a battery connected to a PCS (Power Conditioning System) DC-DC converter is connected to the PCS to compensate the power applied to the ESS.

Another object of the present invention is to provide an active ESS capable of improving instantaneous responsiveness by connecting a supercapacitor in parallel to a battery so that a supercapacitor assists a battery and supplies a compensating power.

It is another object of the present invention to provide an active ESS capable of preventing battery damage due to a peak load by allowing a supercapacitor to supply power by assisting a battery by being connected in parallel to a battery, thereby prolonging the life of the battery.

The active ESS of the present invention includes a grid-connected power generator for generating and transmitting a first power source; An independent power generation source for generating and transmitting a second power source; An auxiliary power supply for generating and outputting a peak auxiliary power for compensating the first power or the second power; A load connected to the grid-connected power generation source and the independent power generation source through a power transmission line; And a PCS that is connected to the grid-connected power generation source, the independent power generation source, and the load by a power transmission line, converts one of the first power source and the second power source to the peak auxiliary power, The power supply unit is connected to the PCS and outputs the power to the first auxiliary power supply. The auxiliary power supply unit is connected in parallel with the battery to charge and discharge the first auxiliary power, And a DC-DC converter that steps up the second auxiliary power to output the peak auxiliary power.

The active ESS of the present invention connects a supercapacitor in parallel to a battery connected to a PCS (Power Conditioning System) that converts DC power to AC power and transfers the AC power to the load. The supercapacitor assists the battery to supply the compensation power, There is an advantage that the life of the battery can be prolonged by preventing the battery damage due to the peak load by allowing the supercapacitor to supply power by assisting the battery by connecting in parallel to the battery.

1 is a block diagram showing the configuration of an active ESS of the present invention,
FIG. 2 is a circuit diagram showing a detailed configuration of the ESS shown in FIG. 1,
3 is a circuit diagram showing a detailed configuration of the open / close circuit shown in Fig. 2,
FIG. 4 is a graph showing discharge characteristics of the ESS shown in FIG. 1; FIG.

Hereinafter, embodiments of the active ESS of the present invention will be described with reference to the accompanying drawings.

1, an active ESS (Energy Storage System) of the present invention includes a grid-connected power generator 110, an independent power generator 120, an auxiliary power supplier 130, a load 140, and a PCS (Power Conditioning System) (150).

The grid-connected power generation source 110 develops itself to generate the first power source P_v1 and transmits the generated first power source P_v1 through the power transmission line PTL. The independent power generation source 120 is connected to the grid-connected power generation source 110 by the power transmission line PTL to generate the second power P_v2 and transmits the generated power via the power transmission line PTL. The auxiliary power supply unit 130 includes a grid auxiliary power source 110 and a peak auxiliary power source P_cor for compensating the first power source P_v1 and the second power source P_v2 generated by the independent power source 120 And the load 140 is connected to the grid-connected power generation source 110 and the independent power generation source 120 via the power transmission line PTL as an end user load that can not generate power. The PCS 150 is connected to the grid-connected power generation source 110, the independent power generation source 120 and the load 140 via the power transmission line PTL and is connected between the first power source P_v1 and the second power source P_v2 One is compensated by the peak auxiliary power (P_cor), then converted into AC power and transmitted to the load (140).

The configuration of the active ESS of the present invention having the above configuration will be described in more detail as follows.

The grid-connected power generation source 110 generates and transmits a first power source P_v1, which is a DC power source, through a power transmission line PTL as shown in FIG. 1 and transmits the first power source P_v1 through a power transmission line PTL or HVDC ) At least one commercial power generation source connected to a transmission network (not shown) and at least one renewable energy generation source. When connected to the power transmission line (PTL), the commercial power generation source and the renewable energy generation source convert the generated power to the first power source (P_v1), which is DC, at the transmission stage, and then transmit the power.

One or more commercial power generating sources constituting the grid-connected power generating source 110 may be one of fossil, hydroelectric and nuclear power plants capable of generating power by themselves after a power failure, and a renewable energy generating source Wind power or solar power plants that can not be developed are used.

1, the independent power source 120 generates and transmits a second power source P_v2, which is a direct current power source, through a power transmission line PTL, and is made up of one or more renewable energy sources, Solar power plants are used. New and renewable energy generators can not develop their own power after a power outage. That is, a wind power or a solar power plant can produce electric power by using wind power or solar light after a power failure, but since a power source for driving a management system (not shown) for managing and controlling the power is required, ) Can not be generated and transmitted.

The auxiliary power supply unit 130 includes a battery 131, a supercapacitor 132, and a DC-DC converter 133 as shown in FIG.

The battery 131 is connected to the PCS 150 and outputs it to the first auxiliary power source P_a1. The battery 131 is connected to a lead accumulator, a nickel cadmium battery, a nickel metal hydride battery, a lithium ion battery, and a lithium polymer battery Is selected and used. The battery 131 is charged by the first power source P_v1 and the second power source P_v2 generated and transmitted to the grid-connected power source 110 or the independent power source 120.

The supercapacitor 132 is connected in parallel to the battery 131 and receives the first sub power source P_a1 to charge and discharge the second sub power source P_a2 and is formed of at least one electric double layer capacitor . That is, a large capacity EDLC is used for the supercapacitor 132.

The DC-DC converter 133 receives the second auxiliary power P_a2, steps it up, and outputs a peak auxiliary power P_cor to compensate the first power P_v1 or the second power P_v2 . The DC-DC converter 133 receives the second auxiliary power P_a2 to stabilize the output of the PCS 150 and steps up or steps down the peak auxiliary power P_cor to output To compensate the first power source (P_v1) or the second power source (P_v2) actively. For example, even when the peak currents of the first power source P_v1 and the second power source P_v2 suddenly change, the DC-DC converter 133 may step up or down the second sub power source P_a2. so that the first auxiliary power P_a1 discharged through the battery 131 is output constantly.

The auxiliary power supply unit 130 is further provided with an opening / closing circuit 134 as shown in FIGS. The opening and closing circuit 134 is connected in series with the supercapacitor 132 to electrically connect or disconnect the auxiliary power supply 130 to the PCS 150 to reduce the consumption of power charged in the battery 131, A blocking switch CB, an LC resonance circuit 134a, a charging resistor R and a thyristor THR.

The circuit breaker switch CB is connected between the battery 131 and the supercapacitor 132 so as to be disposed in series with the battery 131 and is opened and closed by a switch control signal SW_con output from the PCS 150, (130) to or from the PCS (150). This circuit breaker switch CB is a switch having a rating that can withstand high voltages to block the peak auxiliary power source P_cor for compensating the power delivered from the power transmission system to the load 140 which is the end user. Is used. That is, the circuit breaker switch CB is a known circuit breaker switch or the like which is a high-voltage DC breaker.

The LC resonance circuit 134a is connected in parallel to the circuit breaker switch CB and includes a resonance capacitor C and an inductor L. The resonance capacitor C is connected to the supercapacitor And the second auxiliary power source P_a2 discharged from the first auxiliary power source 132 and outputted.

The charging resistor R is connected in series with the LC resonance circuit 134a so that the resonance capacitor C is charged when the circuit breaker switch CB is closed, that is, when the auxiliary power supply 130 is operated, The second auxiliary power source P_a2 discharged from the supercapacitor 132 and charged in the resonance capacitor C during the operation of the power supply unit 130. [

The thyristor THR is connected in parallel to the LC resonance circuit 134a and receives a trigger pulse TRI_p output from the PCS 150 in the normal off state to turn on the circuit breaker CB The arc generated at the time of opening is removed. In the normal off state, while the first power source P_v1 or the second power source P_v2 transmitted to the PCS 50 is compensated by the peak auxiliary power source P_cor output from the auxiliary power source 130, Indicates that thyristor (THR) is off. The circuit breaker switch CB allows the auxiliary power supply 130 and the PCS 150 to be electrically separated from each other when the first power source P_v1 and the second power source P_v2 operate normally. An arc may be generated by flowing a high-voltage direct current through the circuit breaker switch CB when the circuit breaker switch CB is opened and the auxiliary power supply 130 is electrically disconnected from the PCS 150. [

The thyristor THR is turned on in the normal OFF state when the trigger pulse TRI_p output from the PCS 150 is received to prevent the battery 131 or the supercapacitor 132 from being damaged due to the arc . When the thyristor THR is turned on, the LC resonance circuit 134a generates a resonance current by using the voltage charged in the capacitor C for charging and transmits the resonance current to the circuit breaker CB through the thyristor THR, Remove. The arc generated in the circuit breaker switch CB is removed so that the opening and closing circuit 134 safely separates the auxiliary power supply 130 and the PCS 150 electrically.

1, when the first power source P_v1 and the second power source P_v2 are transmitted below a preset reference voltage level, the PCS 150 receives the peak auxiliary power source P_cor from the auxiliary power source 130, And generates and outputs a switch control signal SW_con and a trigger pulse TRI_p in order to electrically separate the first power source P_v1 and the second power source P_v2 from the auxiliary power supply unit 130 when they are respectively higher than the reference voltage level .

The operation of the active ESS of the present invention having the above configuration will now be described.

The active ESS of the present invention supplies the peak auxiliary power source P_cor supplied through the grid-connected power source 110 or the auxiliary power source 130 during the power failure of the independent power source 120 to the PCS 150 for a predetermined period of time The peak auxiliary power P_cor is converted into AC power to be transmitted to the load 140 and the voltage level of the first power source P_v1 or the second power source P_v2 is sensed and compensated. Here, the second power source P_v2 may be supplied to the load 140 alone or may be generated when the power consumption of the load 140 is low and stored in the independent power source 120, And is used as an auxiliary power source for the first power source P_v1.

The operation of detecting and compensating the voltage level of the first power source P_v1 or the second power source P_v2 is performed by first power source P_v1 generated by the grid-connected power source 110, And the second power source P_v2 transmitted from the second power source P_v2 is compared with a previously stored reference voltage level. The reference voltage level is a voltage level that is converted into an AC power source through the PCS 150 and then supplied to the load 140. The first power source P_v1 or the second power source P_v2 is connected to a voltage Level, and stores it in the PCS 150. FIG. Here, the load 140 is composed of consuming loads that are converted into AC power by the PCS 150 and consumed by the first power source P_v1 and the second power source P_v2.

The PCS 150 compares the first power source P_v1 or the second power source P_v2 with the reference voltage level and then supplies the auxiliary power source unit (the first power source P_v1 or the second power source P_v2) 130 and compensates the first power source P_v1 or the second power source P_v2 using the peak auxiliary power P_cor output from the auxiliary power supply unit 130. [ That is, the auxiliary power supply unit 130 is electrically connected to the PCS 150 under the control of the PCS 150 to compensate the first auxiliary power P_a1 output from the battery 131 through the supercapacitor 132 And generates and outputs the second sub power source P_a2.

When the second auxiliary power source P_a2 is output, the DC-DC converter 133 generates a peak auxiliary power source P_cor by stepping up the second auxiliary power source P_a2 to generate a first power source P_v1, 2 power source P_v2 to the voltage level requested by the load 140 and transmitted to the PCS 150. [ The active ESS of the present invention actively compensates the first power source P_v1 or the second power source P_v2 by allowing the peak auxiliary power source P_cor to be stepped up and adjusted through the DC-DC converter 133, The instantaneous responsiveness is improved as in the case of the waveform Wf1 shown in FIG. 4 by applying the in-rush current, that is, the peak current of the load 140, as shown in FIG.

The waveform Wf2 shown in FIG. 4 shows a response state when the inrush current of the load 140 is generated in the conventional active ESS using only the battery 131, and the response is delayed and outputted as compared with the active ESS of the present invention . The voltage level of the peak auxiliary power P_cor output from the active ESS of the present invention is lower than the voltage level of the secondary auxiliary power P_a2 of the supercapacitor 132 following the first auxiliary power P_a1 of the battery 131, ) Of the first auxiliary power source (P_a1). Here, in the graph shown in FIG. 4, the horizontal axis represents time (t), and the vertical axis represents the amount of current (A: Ampare).

When only the battery 131 is applied to the ESS in the case of requesting the peak current of the load 140, the delayed response as in the case of the waveform Wf2 shown in FIG. 4 is stably applied to the first power source P_v1 or the second The power source P_v2 can not be compensated. When the peak current of the load 140 is required, the conventional ESS may be damaged due to the battery 131 being operated forcibly as the discharge time of the battery 131 is delayed from the peak current demand time.

The passive ESS according to the present invention can improve the instantaneous responsiveness by the supercapacitor 132 by connecting the supercapacitor 132 to the battery 131 in parallel to the conventional ESS using only the battery 131. [ Since the instantaneous responsiveness of the load 140 is improved when the peak current of the load 140 is required, the passive ESS of the present invention can prevent unexpected operation of the battery 131 upon request of the peak current to the load 140, Thereby enabling the passive ESS of the present invention to improve the life of the battery 131.

The PCS 150 compares the first power source P_v1 and the second power source P_v2 with the reference voltage level and then determines whether the first power source P_v1 or the second power source P_v2 is higher than the reference voltage level Generates a switch control signal (SW_con) and a trigger pulse (TRI_p) to release the electrical connection with the auxiliary power supply unit (130) in order to reduce consumption. When the switch control signal SW_con is generated and output, it is received at the circuit breaker switch CB of the auxiliary power supply unit 130.

The circuit breaker switch CB is opened when the switch control signal SW_con is received to release the electrical connection between the auxiliary power supply 130 and the PCS 150 to prevent the power charged in the battery 131 from being consumed . An arc may be generated as a high-voltage current flows through the circuit breaker switch CB when the circuit breaker switch CB is opened. When an arc is generated, a current flows continuously through the circuit breaker switch CB so that the electrical connection between the auxiliary power supply 130 and the PCS 150 is maintained. As a result, the battery 131, the supercapacitor 132, The PCS 150 may be damaged.

The PCS 150 generates and outputs a trigger pulse TRI_p in order to remove an arc that may damage the battery 131, the supercapacitor 132 and the PCS 150, and receives the trigger pulse TRI_p from the thyristor THR . The thyristor THR is turned on in the off state when the trigger pulse TRI_p is received, and the resonance current generated in the LC resonance circuit 134a is applied to the circuit breaker switch CB to remove the arc. The active ESS according to the present invention eliminates the arc generated in the circuit breaker switch CB by using the resonance current of the LC resonance circuit 134a so that the electrical connection between the auxiliary power supply 130 and the PCS 150 is stable Can be released.

The active ESS of the present invention can also prevent the damage of the battery 131, the supercapacitor 132 and the PCS 150 due to the arc and the first power source P_v1 or the second power source P_v2 can be prevented from being damaged by the PCS 150 It is possible to prevent leakage current through the supercapacitor 132 by preventing the self discharge of the supercapacitor 132 unnecessarily while being normally transmitted, so that the power consumption of the battery 131 can be reduced to maximize the discharge time.

As described above, in the active ESS of the present invention, a supercapacitor is connected in parallel to a battery connected to a PCS (Power Conditioning System) that converts DC power to AC power and transfers the AC power to the load. The instantaneous responsiveness can be improved by connecting the battery to the battery in parallel, so that the supercapacitor assists the battery to supply power, thereby preventing battery damage due to the peak load, thereby prolonging the life of the battery.

The active ESS of the present invention is applied to the power transmission industry or related parts manufacturing industry.

110: Grid-connected power generation plant 120: Independent power generation plant
130: auxiliary power supply unit 131: battery
132: super capacitor 133: DC-DC converter
134: open / close circuit 140: load
150: PCS

Claims (9)

A grid-connected power generation source for generating and transmitting a first power source;
An independent power generation source for generating and transmitting a second power source;
An auxiliary power supply for generating and outputting a peak auxiliary power for compensating the first power or the second power;
A load connected to the grid-connected power generation source and the independent power generation source through a power transmission line;
And a PCS that is connected to the grid-connected power generation source, the independent power generation source, and the load by a power transmission line, converts one of the first power source and the second power source to the peak auxiliary power, (Power Conditioning System)
The auxiliary power supply unit includes a battery connected to the PCS and outputting a first auxiliary power, a supercapacitor connected in parallel with the battery to charge and discharge the first auxiliary power to output a second auxiliary power, 2 DC-DC converter for stepping up with an auxiliary power supply and outputting the peak auxiliary power,
The auxiliary power supply unit may further include an opening / closing circuit connected in series with the battery to electrically connect or disconnect the auxiliary power supply unit to / from the PCS. The opening / closing circuit may include a connection between the battery and the supercapacitor A circuit break switch opened and closed by a switch control signal output from the PCS to electrically connect or disconnect the auxiliary power supply to the PCS; An LC resonance circuit connected in parallel to the circuit breaker switch and including a resonance capacitor and an inductor; A charging resistor connected in series with the LC resonance circuit to charge the resonance capacitor when the circuit breaker switch is closed; And a thyristor connected in parallel to the LC resonance circuit and receiving a trigger pulse output from the PCS in a normal off state to remove an arc generated when the circuit breaker switch is opened Active Energy Storage System (ESS). The system of claim 1, wherein the grid-connected power generation source generates and transmits a first power source, which is a DC power source, through a power transmission line, a commercial power source connected to an HVDC (Hihg Voltage Direct Current) And the commercial power generation source is one of fossil, hydropower and nuclear power plants, and the renewable energy generation source is an active type ESS using wind power or solar power generation plant. 2. The active ESS according to claim 1, wherein the independent power source generates and transmits a second power source, which is a direct current power source, through a power transmission line, and the wind power or solar power plant is used. The active ESS according to claim 1, wherein at least one of a lead-acid battery, a nickel-cadmium battery, a nickel metal hydride battery, a lithium ion battery and a lithium polymer battery is selected. The active ESS according to claim 1, wherein the supercapacitor of the auxiliary power supply unit comprises at least one electric double layer capacitor (EDLC). The active ESS according to claim 1, wherein the DC-DC converter of the auxiliary power supply unit receives the second auxiliary power and outputs a peak auxiliary power by stepping up or stepping down. delete delete The method of claim 1, wherein the PCS receives a peak auxiliary power from an auxiliary power supply when the first power and the second power are transmitted below a preset reference voltage level, Active ESS which generates and outputs switch control signal and trigger pulse to be electrically separated from auxiliary power supply.

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