KR102150480B1 - Balancing energy storage system using hopping battery cell - Google Patents

Abstract

The present invention relates to a balancing energy storage system for providing communication devices using an auxiliary cell which is used in communication equipment which supplies charging power of the auxiliary cell to a load or enables power sales while adjusting a balance between charging cells by storing the charging power for the cell in which an imbalance occurs in the auxiliary cell when a charging imbalance occurs between the charging cells.

Description

Balancing energy storage system for providing communication devices using auxiliary cells {BALANCING ENERGY STORAGE SYSTEM USING HOPPING BATTERY CELL}

The present invention is used in communication equipment that supplies charging power from the auxiliary cells to a load or enables power sales while adjusting the balance between charging cells by storing charging power for the cells in which the imbalance occurs in an auxiliary cell when charging imbalance occurs between charging cells. It relates to a balancing energy storage system for providing a communication device using an auxiliary cell.

Recently, energy demand has been steadily increasing around the world, and new energy demand continues to occur as income increases, quality of life and various services are advanced, and the dependence on electricity is increasing.

In particular, power problems such as depletion of fossil fuels, reduction of pollution, and power disruption at the time of concentration of power use are becoming issues, and improvement in energy supply and demand is urgent as many of the energy sources depend on crude oil and nuclear power.

Accordingly, an energy supply system using battery cells has emerged as one of the efficient energy supply methods. This energy supply system stores surplus electricity or renewable energy and supplies it when needed.

Therefore, it is possible to store and use electric power when necessary, thereby improving energy use efficiency, enhancing renewable energy utilization, and stabilizing the power supply system, and thus, its importance as one of the new growth engine industries is emerging.

Nevertheless, in the conventional energy supply system, charging imbalance occurs between charging cells from the beginning or during charging, and thus, in the process of repetitive charging and discharging of a specific charging cell relatively many times, the life of the cell is shortened and the supply voltage is unstable. do.

Republic of Korea Patent Publication No. 2017-0013537

The present invention is used in communication equipment that supplies charging power from the auxiliary cells to a load or enables power sales while adjusting the balance between charging cells by storing charging power for the cells in which the imbalance occurs in an auxiliary cell when charging imbalance occurs between charging cells. It is intended to provide a balancing energy storage system for providing communication devices using auxiliary cells.

To this end, the balancing energy storage system for providing a communication device using an auxiliary cell according to the present invention comprises: a charging power supply for supplying charging power including renewable power or surplus produced power; A plurality of charging cells each receiving power from the charging power supply, charging, and discharging to a load; A cell monitor for monitoring the state of charge of the charging cells, respectively; A charging controller for switching and controlling charging power supplied from the charging power supply to the charging cells according to the charging state of the charging cells detected by the cell monitor; At least one or more charging power supplied to the upper cell by the charging controller when an upper cell charged above the reference value is detected among the plurality of charging cells to apply charging power to the communication equipment. Auxiliary cells; And a main controller that transmits and controls the DC power charged in the auxiliary cell to a commercial power system through an inverter and a watt hour meter for sale, when the amount of charge of the auxiliary cell is higher than the reference value, wherein the charging controller is detected by the cell monitor. And a time checking unit for switching and controlling charging power supplied from the charging power supply to the auxiliary cells according to the charging state of the auxiliary cells, and the time checking unit of the charging power supplied from the charging power supply to each of the auxiliary cells. It is characterized in that switching control is performed by calculating time.

In addition, it further comprises a load-side switching switch installed between the output terminal and the load of the charging cell, wherein the load-side switching switch is connected to the output terminal of the charging cell, the output terminal of the auxiliary cell and the commercial power system, any of which It is desirable to be switched over to connect one to the load.

In addition, the charging power supply includes an input terminal for receiving charging power produced by a regenerative generator; A power cut-off switch installed at a rear end of the input terminal; A regenerative power rectifier for rectifying the AC charging power supplied through the power cut-off switch into a DC charging power; And a PWM converter that changes the size of the DC charging power according to the pulse width control signal provided from the PWM controller and provides the charging controller to the charging controller, wherein the main controller includes a size of the charging power input through the input terminal and Controls the PWM controller according to one or more of the sizes of charging power supplied to the load from the charging cell, and the main controller monitors the power cut-off switch, and when switching off the power cut-off switch, the It is desirable to switch off the sell-off switch provided between the auxiliary cell and the commercial power system.

In the present invention as described above, when a charging imbalance occurs between charging cells for the purpose of charging and discharging, charging power is stored in an auxiliary cell to adjust the balance between charging cells. Therefore, it is possible to provide a stable power supply while preventing a shortening of the life of the charging cell.

In addition, the present invention enables the power charged in the auxiliary cell to be supplied to a load under a specific condition or sold as surplus power in order to adjust the balance between charging cells as described above. Therefore, it stabilizes energy supply and demand and directs it to profits.

1 is a block diagram showing a balancing energy storage system for providing a communication device using an auxiliary cell according to the present invention.
2 is a diagram showing a charging power auxiliary circuit according to the present invention.
3 is a block diagram showing a charging power supply according to the present invention.

Hereinafter, a balancing energy storage system for providing a communication device using an auxiliary cell according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1, a balancing energy storage system using an auxiliary cell according to the present invention includes a charging power supply 110, a plurality of charging cells 120, a cell monitor 130, a charging controller 140, and an auxiliary cell 150. And a main controller 160.

In addition, the present invention includes a load-side changeover switch 170 and a sell switch 180 as another preferred embodiment, and further includes a power converter such as an inverter 181 or a sell watt hour meter 182 as an additional configuration. do.

According to this configuration, when a charge imbalance occurs between the charging cells 120 for charging and discharging, the charging circuit for the cell in which the imbalance occurs is switched to the auxiliary cell 150 and charged to adjust the balance between the charging cells 120 . Therefore, it is possible to provide a stable power supply while preventing the life of the charging cell 120 from being shortened.

In addition, while the balance between the charging cells 120 is adjusted, the power charged in the auxiliary cells 150 is supplied to a load under specific conditions or sold as surplus power. Therefore, it stabilizes energy supply and demand and directs it to profits.

More specifically, the charging power supply 110 stores and supplies charging power to the charging cell 120 to supply it, and further supplies charging power to the auxiliary cell 150 by assisting the charging circuit (line). do.

Rechargeable power includes various power sources including renewable energy such as hydro energy, geothermal energy, and solar energy, late-night power with reduced load, as well as communication equipment systems that can be utilized through the supply of charging power. Supply power to the energy supply system.

A specific embodiment of the charging power supply 110 will be described in detail again with reference to FIG. 3 below.

Next, the charging cells 120 are the main configuration of the energy storage (supply) system, and are generally composed of a plurality of battery pack types, each receiving power from the charging power supply 110 and charging them, and then discharging them to the load LD. .

These charging cells 120 are supplied with charging power from the charging power supply 110 in a state in which a plurality of charging cells 120 are connected to each other in a series, parallel, or series-parallel manner. Typically, each charging cell 120 is a lithium ion battery or a lithium polymer. It consists of a battery.

The cell monitor 130 monitors the charging state of the charging cells 120 respectively, and preferably also monitors the charging state of the auxiliary cell 150 to be described later. The monitoring result is provided to the charging controller 140, and preferably also provided to the main controller 160.

Specifically, the cell monitor 130 monitors and provides the voltage, current, temperature, and abnormal states of the charging cell 120 and the auxiliary cells 150 to prevent overcharge, overdischarge, overcurrent protection, and short-circuit protection in the system. Make it possible to provide.

The charging controller 140 receives the detection value of the charging state of the charging cell 120 from the cell monitor 130, and according to the current charging state of the detected charging cell 120, the charging cell ( Each of the charging power supplied to 120) is controlled by switching.

For example, the charging controller 140 interlocks with the charging cells 120 to prevent overcharging and overdischarging so that charging is performed within a range of 20% to 80% of the maximum rating of the charging cell 120, and furthermore In case of over-current protection and short-circuit protection circuits are activated.

In particular, the charging controller 140 charges the charging cell 120 under the control of the main controller 160, which will be described again below, or connects the charging circuit to the auxiliary cell 150, thereby hopping the charging circuit (line). hopping).

To this end, as shown in FIG. 2, the charge controller 140 includes a microcomputer 141 and a plurality of charge control switches 142 connected to the charging cell 120. In addition, the charging control switch 142 is connected in parallel to at least one auxiliary cell 150 by branching.

Accordingly, the charging controller 140 charges the charging cell 120 under the control of the microcomputer 141 or charges the auxiliary cell 150 by switching switching. The assistance of the charging circuit serves to charge the auxiliary cells 150 in a bypass when a charge imbalance occurs between the charging cells 120 as described again below.

Meanwhile, in addition to the above-described embodiment, the charging controller 140 is a charging power supplied from the charging power supply 110 to the auxiliary cell 150 according to the charging state of the auxiliary cell 150 detected by the cell monitor 130. Each further includes a time check unit (T / C) for controlling the switching, the time check unit (T / C) is a charging power supplied to each of the auxiliary cells 150 from the charging power supply 110 Switching can be controlled by calculating the time of.

That is, the time required to be charged to a desired amount of charge compared to the capacity of one auxiliary cell 150 is measured and calculated by the time checking unit (T/C), but the information is transmitted to the microcomputer 141 and the auxiliary cell 150 ) To determine the amount of charge (see Fig. 2)

The auxiliary cell 150 is for extending the life of the charging cells 120, improving performance, and supplying stable power by adjusting the charging imbalance between the charging cells 120, and is basically overcharged under the control of the charging controller 140. When the charging cell 120 occurs, the charging power is received instead.

In particular, the auxiliary cell 150 is supplied to the upper cell by the charge controller 140 when a'higher cell' charged above the reference value among the plurality of charging cells 120 is detected. It is charged by receiving charging power, and at least one is provided.

That is, when an upper cell of the charging cells 120 or more is detected by the cell monitor 130 and notified to the charging controller 140, the charging controller 140 transfers the charging circuit of the upper cell to the auxiliary cell 150. It is switched so that the auxiliary cell 150 is charged instead of the upper cell.

At the same time, the charging cells 120 other than the upper cell among the charging cells 120 are continuously charged by the charging controller 140, and this process is repeated to equalize the charging level of the various charging cells 120. .

In addition, the power charged in the auxiliary cell 150 through the charging circuit assistance of the upper cell is sent to the power system (PS) through the DC/AC inverter 181 and the watt hour meter 182 for sale, so that power can be sold or if necessary. Supply directly to the load.

As described above, when the charge amount of the auxiliary cell 150 is higher than the reference value, the main controller 160 converts the DC power charged in the auxiliary cell 150 to the commercial power system through the inverter 181 and the watt hour meter 182 for sale. Transmission control with (PS).

To this end, the main controller 160 controls the switching of the output terminal of the auxiliary cell 150, and the auxiliary cell 150 is discharged by switching control, through which it is possible to continuously assist the charging circuit and charge the auxiliary cell 150. Let's do it.

On the other hand, in the present invention made of the configuration as described above, the auxiliary cell 150 is also preferably a plurality so that sufficient assistance for a long time is possible. The entire group of auxiliary cells 150 including a plurality of auxiliary cells 150 is connected to the charging cell 120 in parallel.

In addition, the cell monitor 130 monitors the charging state of the auxiliary cell 150, respectively, and the charge controller 140 is charged with the power supply 110 according to the charging state of the auxiliary cell 150 detected by the cell monitor 130. ), each switching control of the charging power supplied to the auxiliary cell 150.

Therefore, each of the plurality of auxiliary cells 150 functions as an auxiliary cell 150 for a relatively heavily charged upper cell among the charging cells 120, and at this time, the charge controller 140 is relatively The order of charging is controlled by analyzing the upper cells with a lot of auxiliary (charging).

In addition, as shown in Figure 1, the present invention further includes a load-side switching switch 170 installed between the output terminal and the load of the charging cell 120. The load-side changeover switch 170 is connected to an output terminal of the charging cell 120, an output terminal of the auxiliary cell 150 and a commercial power system P-S.

Specifically, the common output terminal of the load-side selector switch 170 is connected to the load LD, and the three input terminals are connected to the output terminal of the charging cell 120, the output terminal of the auxiliary cell 150, and the commercial power system (PS), respectively. According to the switching, one of them is connected to the load LD.

Accordingly, power is supplied to the load LD through the charging cell 120 whose main purpose is to supply power in the first order, and secondly, when the charge amount of the auxiliary cell 150 is more than the reference value, the auxiliary cell 150 supplies power to the load. In the third case, when the above-described cells cannot be charged, power is supplied from the commercial power system (PS) to the load.

As shown in FIG. 3, the charging power supply 110, which has not been described in detail above, supplies regenerative power or surplus power. For example, an input terminal 111, a power cut-off switch 112, a regenerative power rectifier 113, and Includes a PWM converter 114.

Here, the input terminal 111 is a physical terminal for receiving charging power produced by the power generation side into the system according to the present invention, and receiving charging power from late-night power (surplus power) or various renewable energy generators.

The power cut-off switch 112 is installed at the rear end of the input terminal 111, and supplies charging power to the rear end or cuts off the supply by switching on or off. This cuts off standby power for subsequent components.

The regenerative power rectifier 113 rectifies the AC charging power supplied through the power cut-off switch 112 into DC charging power, and converts the input AC power into DC power using, for example, a full bridge converter.

In addition, the regenerative power rectifier 113 is provided with a smoothing capacitor and/or filter on the full bridge to remove nipples to increase smoothness and to supply DC power suitable for charging the cell.

The PWM converter 114 changes the size of the DC charging power according to the pulse width control signal provided from the PWM controller 114a and provides it to the charging controller 140. For example, the PWM converter 114 adjusts the power level by adjusting the Pulse Width Ratio (PWR).

At this time, the main controller 160 controls the PWM controller according to one or more of the size of the charging power input through the input terminal 111 and the size of the charging power supplied from the charging cell 120 to the load. Through this, the optimum level is adjusted according to the input and discharge environment.

In addition, the main controller 160 monitors the power cut-off switch 112 of the charging power supply 110, and when the power cut-off switch 112 is switched off, the auxiliary cell 150 and the commercial power system ( PS) switches off the sell switch 180 provided between.

Accordingly, when surplus power (late-night power) or charging power supplied from various renewable energy generators is insufficient or interrupted, the sale of power is stopped and emergency standby is enabled for the load LD.

In the above, specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention are not limited to these specific embodiments, and that various modifications and variations are possible within the scope of not changing the subject matter of the present invention. You will understand when you grow up.

Therefore, the embodiments described above are provided to completely inform the scope of the invention to those of ordinary skill in the technical field to which the present invention belongs, and should be understood as illustrative and non-limiting in all respects, The invention is only defined by the scope of the claims.

110: charging power supply
120: charging cell
130: cell monitor
140: charge controller
150: secondary cell
160: main controller
170: load-side selector switch
180: sell switch
181: inverter
182: watt hour meter for sale
LD: load
PS: power system

Claims (4)

A charging power supply 110 for supplying charging power including renewable power or surplus produced power;
A plurality of charging cells 120 each receiving power from the charging power supply 110, charging, and discharging to a load;
A cell monitor 130 for monitoring the charging state of the charging cells 120, respectively;
A charging controller 140 for switching and controlling charging power supplied from the charging power supply 110 to the charging cell 120 according to the charging state of the charging cell 120 detected by the cell monitor 130;
When an upper cell charged above the reference value among the plurality of charging cells 120 is detected, the charging controller 140 receives the charging power supplied to the upper cell and is charged. At least one auxiliary cell 150 for applying charging power to communication equipment; And
If the charge amount of the auxiliary cell 150 is greater than or equal to the reference value, the main controller 160 for controlling the transmission of DC power charged in the auxiliary cell 150 to the commercial power system PS through an inverter and a watt hour meter for sale; Include,
The charging controller 140 is for switching and controlling the charging power supplied from the charging power supply 110 to the auxiliary cell 150 according to the charging state of the auxiliary cell 150 detected by the cell monitor 130. Includes a time check unit (T/C), and the time check unit (T/C) controls switching by calculating the time of charging power supplied from the charging power supply 110 to each of the auxiliary cells 150 And
The charging power supply 110 includes an input terminal 111 for receiving charging power produced by a regenerative generator, a power cut-off switch 112 installed at a rear end of the input terminal 111, and the power cut-off switch 112. A regenerative power rectifier 113 that rectifies the AC charging power supplied through the DC charging power to a DC charging power and provides the charge controller 140 by changing the size of the DC charging power according to the pulse width control signal provided by the PWM controller. Including a PWM converter 114, wherein the main controller 160 is any one of the size of the charging power input through the input terminal 111 and the size of the charging power supplied to the load from the charging cell 120 The PWM controller is controlled according to the above, and the main controller 160 monitors the power cut-off switch 112, and the auxiliary cell 150 is switched off when the power cut-off switch 112 is switched off. A balancing energy storage system using an auxiliary cell used in communication equipment, characterized in that switching off the sell switch 180 provided between the and commercial power system (PS).
The method of claim 1,
Further comprising a load-side switching switch 170 installed between the output terminal and the load of the charging cell 120,
The load-side changeover switch 170 is connected to the output terminal of the charging cell 120, the output terminal of the auxiliary cell, and the commercial power system PS, and is switched to connect any one of them to the load. Balancing energy storage system using auxiliary cells used in communication equipment.
delete The method of claim 2,
The charging power supply 110,
An input terminal 111 for receiving charging power produced by the regenerative generator;
A power cut-off switch 112 installed at a rear end of the input terminal 111;
A regenerative power rectifier 113 rectifying the AC charging power supplied through the power cut-off switch 112 into a DC charging power; And
Including; a PWM converter 114 for changing the size of the DC charging power supply to the charging controller 140 according to the pulse width control signal provided by the PWM controller;
The main controller 160 controls the PWM controller according to any one or more of the size of the charging power input through the input terminal 111 and the size of the charging power supplied from the charging cell 120 to the load,
The main controller 160 monitors the power cut-off switch 112 and is provided between the auxiliary cell 150 and the commercial power system (PS) when switching off at the time of the power cut-off switch 112 Balancing energy storage system using an auxiliary cell used in communication equipment, characterized in that switching off the sold switch 180.

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