KR20160114534A - Acid/alkaline hybrid resonance battery device with damping function - Google Patents

Abstract

The present invention relates to an acid-alkaline hybrid resonance battery device having a damping function. The acid/alkaline hybrid resonance battery having a damping function comprises a plurality of similar battery cells that are connected to each other in series or in parallel. All battery cells include an acid rechargeable cell unit and an alkaline rechargeable cell that are electrically connected to each other in parallel. The acid rechargeable cell unit includes at least one acid rechargeable cell and the alkaline rechargeable cell unit includes at least two alkaline rechargeable cells that are connected to each other in series. The acid rechargeable cell unit has an electrical potential and capacity that are close to or identical to the electrical potential and the capacity of the alkaline rechargeable cell unit, and thereby a resonance damping effect is produced between the acid rechargeable cell unit and the alkaline rechargeable cell unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an ACID / alkaline hybrid resonance battery device having a damping function,

The present invention relates to an acid / alkali hybrid resonance battery device having a damping function, in which an acid rechargeable cell unit and an alkaline rechargeable cell unit are connected in parallel to form individual battery cells of a battery device .

A cell is a basic unit constituting a battery. Depending on the electrolyte used, the rechargeable cells can generally be divided into two types: acid batteries and alkaline batteries. The electrolytic solution for the acid battery may be an aqueous sulfuric acid solution. An example of such a acid cell is a lead-acid battery. This lead-acid battery has some disadvantages, such as large volume, large weight, pollution inducing and slow oxidation-reduction reaction, and is therefore being replaced by a lithium iron phosphate battery. The acid secondary cell is capable of storing electrical energy in the form of current so that it is damaged when the stored current I is fully discharged (i.e., when I = 0).

The electrolytic solution for an alkaline secondary cell is mainly an aqueous solution of calcium hydroxide. Alkaline zinc-manganese batteries, nickel-cadmium batteries and nickel-hydrogen batteries are some examples of such alkaline rechargeable cells. The alkaline rechargeable cell can store electrical energy in the form of a voltage, so that it is damaged when discharged to zero voltage (i.e., when V = 0). When discharged to a voltage of less than 1.0 V, the battery is generally dead, and can no longer be discharged. This alkaline rechargeable cell must be charged with a very small current, which usually requires more than 24 hours to fully charge. Further, the alkaline secondary cell can not be recharged only a few times, which is inconvenient to use. In addition, alkaline rechargeable cells tend to increase in temperature during charging and discharging.

All electric devices using the transfer cell as a power source are provided with a battery management system (BMS) therein. Generally, the battery management system has a function of measuring the battery voltage to prevent or avoid battery over discharge, overcharge, overheating, and other abnormal conditions. In an electrical apparatus using a rechargeable cell connected in multiple parallel with a power supply, if one of the battery management systems detects a rechargeable cell having an insufficient voltage, the electrical device stops supplying power. Most consumers do not understand why a battery that stores electrical energy inside can not discharge and cause a load crash. A sudden crash of the load, especially if the power supply is suddenly lost during operation of the motor ratio hiccup, can cause damage.

The main object of the present invention is to provide a damping function which is formed by a plurality of similar battery cells connected in series or in parallel and all battery cells internally make a self-resonant damping effect, And an acid / alkaline hybrid resonance battery device having the same.

It is another object of the present invention to provide an acid / alkali hybrid resonance battery device having a damping function which enables an automatic balance of internal potentials and thus does not require a battery management system (BMS).

In order to achieve the above object and other objects, an acid / alkali hybrid resonance battery device having a damping function provided in accordance with the present invention is formed of a plurality of similar battery cells connected in series or in parallel. All battery cells include an acid rechargeable cell unit and an alkaline rechargeable cell unit. Due to the resonant damping effect between the acid rechargeable cell unit and the alkaline rechargeable cell unit, a balanced electrical potential therebetween can be automatically achieved, enabling fast charging and fast discharging of the battery device.

The acid secondary cell unit and the alkaline rechargeable cell unit are electrically connected in parallel. The acid rechargeable cell unit comprises at least one acid rechargeable cell, and the alkaline rechargeable cell unit comprises at least two alkaline rechargeable cells connected in series. The acid rechargeable cell unit has a similar electric potential and capacity to the alkaline rechargeable cell unit, so that the resonant damping effect between the acid rechargeable cell unit and the alkaline rechargeable cell unit is calculated.

The acid secondary cell may be a lithium phosphate (LFP) acid rechargeable cell; The alkaline rechargeable cell may be a nickel-zinc alkaline rechargeable cell.

In the case of having at least one acid rechargeable cell in the acid rechargeable cell unit, the acid rechargeable cells can be connected in parallel, which can lead to a capacity increase in the acid rechargeable cell unit. The alkaline rechargeable cells in the alkaline rechargeable cell unit can be connected in series, thereby resulting in a capacity increase in the alkaline rechargeable cell unit.

According to the present invention, there is provided a battery pack comprising: a plurality of similar battery cells connected in series or in parallel, wherein all battery cells have a damping function that internally makes a self-resonant damping effect, An acid / alkaline hybrid resonant battery device is provided.

There is also provided an acid / alkaline hybrid resonant battery device having a damping function which enables an automatic balance of internal potentials and thus does not require a battery management system (BMS).

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.
1 is a view showing a structure of an acid / alkali hybrid resonance battery device having a damping function according to a first embodiment of the present invention.
2 is a view showing the structure of one of a plurality of battery cells forming the battery device of FIG.
3 is a block diagram illustrating the present invention being charged with a damping charging device.
4 is a view showing a structure of an acid / alkali hybrid resonance battery device having a damping function according to a second embodiment of the present invention.
5 is a view showing the structure of one of a plurality of battery cells forming the battery device of FIG.

Please refer to Fig. 1 and Fig. Here, the structure of the acid / alkali hybrid resonance battery device having the damping function according to the first embodiment of the present invention is shown. For simplicity and clarity, the present invention is referred to briefly as a battery device and is designated by reference numeral 10. As shown, the battery device 10 of the first embodiment is formed of a plurality of similar battery cells 11 connected in series or in parallel. All the battery cells 11 include an acid rechargeable cell unit 12 and an alkaline rechargeable cell unit 13, which are electrically connected in parallel.

In the first embodiment shown above, the acid rechargeable cell unit 12 is composed of one acid rechargeable cell 121, and the alkaline rechargeable cell unit 13 is composed of two And an alkaline rechargeable cell 131. The acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 are electrically connected in parallel. The acid rechargeable cell unit 12 has an electric potential close to or the same as that of the alkaline rechargeable cell unit 13. More specifically, the acid rechargeable cell unit 12 preferably has an electrical potential of about 90% to 110% of the electrical potential of the alkaline rechargeable cell unit 13. The best battery performance can be achieved when the acid rechargeable cell unit 12 has the same electric potential as the alkaline rechargeable cell unit 13. In general, the commercially available acid rechargeable cell 121 has an electrical potential of 3.2 to 3.6 V, and the commercially available alkaline rechargeable cell 131 has an electrical potential of about 1.6 to 1.8 V . The battery device 10 in which the acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 can have the same electric potential does not yet exist.

The acid rechargeable cell 121 and the alkaline rechargeable cell 131 are made of different materials and thus have different energy levels. Basically, the acid rechargeable cell unit 12 is suitable for storing electrical energy in the form of current, and the alkaline rechargeable cell unit 13 is suitable for storing electrical energy in the form of a voltage.

The acid rechargeable cell unit 12 has a capacity close to or the same capacity as the alkaline rechargeable cell unit 13. More specifically, the acid rechargeable cell unit 12 preferably has a capacity of about 90 to 110% of the capacity of the alkaline rechargeable cell unit 13. The best battery performance can be achieved when the acid rechargeable cell unit 12 has the same capacity as the alkaline rechargeable cell unit 13. However, since the real capacity of the second cells 121 and 131 is the work W that can be accommodated by the cell, that is, the work W = voltage (V) x current (I) x time (T) It is not easy for the cell unit 12 to have the same real work capacity as the alkaline rechargeable cell unit 13.

The acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 are arranged such that the energy levels thereof are different from each other and the energy level between the acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 is completely A balanced electrical potential must be achieved. Therefore, the temporary voltage unbalance between the acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 during the charging and discharging process of the battery cell 11, that is, the slightly larger voltage difference, Unit 13 has a high temporal electrical potential to automatically transfer the stored electrical energy to the acid rechargeable cell unit 12 having a lower electrical potential than the alkaline rechargeable cell unit 13, The chargeable cell unit 12 has a high temporal electrical potential to automatically transfer the stored electrical energy to the alkaline rechargeable cell unit 13 having a lower electrical potential than the acid rechargeable cell unit 12 . As a result, the electric potentials of the acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 become gradually equal and balanced. This automatic internal self-resonant condition produces a damping effect. Even when the battery cell 11 is not in the charging and discharging process, the internal self-resonance of the battery cell 11 still exists, yielding a damping effect. This makes the electric potentials of the acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 equal to or close to each other, resulting in a balanced state.

In the first embodiment illustrated in Figs. 1 and 2, the acid rechargeable cell unit 12 is composed of one 3.2 to 3.6V acid rechargeable cell 121, and the alkaline rechargeable cell unit 13 consist of two serially connected 1.6 to 1.8V alkaline rechargeable cells 131. The two- That is, the acid rechargeable cell 121 has an electric potential of 3.2 to 3.6 V, which is close to the total electric potential of 3.2 to 3.6 V of the two alkaline rechargeible cells 131. Therefore, the electric potential of the acid rechargeable cell unit 12 is about 90 to 110% of the electric potential of the alkaline rechargeible cell unit 13. [ In addition, the acid rechargeable cell 121 has a capacity of 20 Ah, and the alkaline rechargeable cell 131 has a capacity of 20 Ah. Therefore, the capacity of the acid rechargeable cell unit 12 is in the range of 90 to 110% of the capacity of the alkaline rechargeable cell unit 13. [ Thus, the acid rechargeable cell unit 12 can have a close proximity to the real work capacity of the alkali rechargeable cell unit 13.

The acid rechargeable cell 121 may be a lithium iron phosphate (LFP) acid rechargeable cell; The alkaline rechargeable cell 131 may be a nickel-zinc alkaline rechargeable cell.

The acid / alkali hybrid resonance battery device 10 having the damping function according to the present invention should be charged with a charging device having a damping function, such as the damping charging device disclosed in Taiwan Utility Model M484854. See FIG. The charging device 20 includes a power output unit 21, a control circuit 22, a damping inductor 23, and a high frequency oscillation switch 24. The power output unit 21 is connected to the electric energy generating device 30 and increases or decreases the voltage of the electric energy output by the electric energy generating device 30 and outputs the voltage- Is used. The acid / alkaline hybrid resonance battery device 10 is connected to a positive terminal for the damping inductor 23 and a negative terminal for the high-frequency oscillation switch 24. The electric energy generating device 30 may be a renewable energy generator or a grid power source. When the high frequency oscillation switch 24 of the charging device 20 is operated, the damping inductor 23 alternately stores and discharges electric energy at a high frequency. When the high-frequency oscillation switch 24 is turned on, the damping inductor 23 stores electric energy. On the other hand, when the high-frequency oscillation switch 24 is OFF, the damping inductor 23 discharges the stored electric energy to charge the acid / alkaline hybrid resonance battery device 10. Therefore, the electric energy discharged from the damping inductor 23 to charge the battery device 10 is electric energy having a frequency response. Then, the battery device 10 can discharge the load 40 to operate it.

The acid rechargeable cell unit 12 and the alkaline rechargeable cell unit 13 take a voltage balance therebetween through instantaneous high frequency resonance, which is a damping effect. Since all of the battery cells 11 in the battery device 10 generate self-resonance without causing a temperature rise during the charging and discharging processes, the battery device 10 can have a longer lifetime. The electric potentials of the acid rechargeable battery unit 12 and the alkaline rechargeable battery unit 13 are automatically equal to or close to each other and become balanced so that there is no need to use the battery management system (BMS) any more . As a result, the electrical equipment does not require a BMS circuit board, thereby reducing manufacturing costs and overall overall weight reduction.

More charging and discharging paths can be provided in the battery device 10 since all the battery cells 11 of the battery device 10 have a self-resonating damping characteristic, Provided in the device 10, faster charging and discharging becomes possible.

4 and 5 show a battery device 10 according to a second embodiment of the present invention. In the second embodiment, the acid rechargeable cell unit 12 in all the battery cells 11 of the battery device 10 is composed of two 3.2 to 3.6 V acid rechargeable cells 122 connected in parallel And the alkaline rechargeable cell unit 13 is composed of two 1.6 to 1.8 V alkaline rechargeable cells 132 connected in series. Therefore, the electric potential of the acid rechargeable cell unit 12 is 90 to 110% of the alkaline rechargeable cell unit 13. In addition, all acid rechargeable cells 122 have a capacity of 1250 mAh, and the alkaline rechargeable cells 132 have a capacity of 2500 mAh. That is, the capacity of the acid rechargeable cell 122 is half of the capacity of the alkaline rechargeable cell 132. In other words, the capacity of the acid rechargeable cell 122 is about 45 to 55% of the capacity of the alkaline rechargeible cell 132. Thus, the acid rechargeable cell unit 12 has a total capacity of 2500 mAh (i.e., 1250 mAh x 2 = 2500 mAh), which is in the range of 90 to 110% of the total capacity of the alkaline rechargeable cell unit 13 I will. Thus, two acid rechargeable cells 122 are connected in parallel, and the capacity of the acid rechargeable cell unit 12 can be increased to a level close to the capacity of the alkaline rechargeable cell unit 13 .

In short, due to the resonant damping effect between the acid rechargeable cell unit 12 and the alkaline rechargeible cell unit 13, the battery device 10 provided according to the present invention has the following characteristics:

(1) The electrical potential balance between the acid rechargeable cell unit 12 and the alkali rechargeable cell unit 13 can be automatically achieved without requiring the provision of the battery management system (BMS).

(2) The internal resistance between the acid rechargeable battery unit 12 and the alkaline rechargeable battery unit 13 is low, which does not cause a rise in the temperature of the battery device 10, Operation.

(3) The number of battery cells 11 connected in series or in parallel in the battery device 10 can be increased, thereby not only increasing the voltage for energy storage and increasing the discharge current, Discharge path to enable faster charging and discharging of the battery device 10. [

Although the present invention has been described with a few preferred embodiments, numerous modifications and variations within the described embodiments can be made within the scope and spirit of the invention, and the invention is limited only by the following claims .

INDUSTRIAL APPLICABILITY The present invention can be used in the industry of an acid / alkali hybrid resonance battery device having a damping function.

10: Battery device
11: Battery cell
12: acid rechargeable cell unit
13: alkaline rechargeable cell unit

Claims (10)

An acid / alkali hybrid resonance battery device having a damping function,
A plurality of similar battery cells connected in series or in parallel;
All of said battery cells include an acid rechargeable cell unit and an alkaline rechargeable cell unit electrically connected in parallel;
Wherein said acid rechargeable cell unit comprises at least one acid rechargeable cell, said alkaline rechargeable cell unit comprising at least one alkaline rechargeible cell;
When there is at least one alkaline rechargeable cell in the alkaline rechargeable cell unit, the alkaline rechargeable cell is connected in series;
Wherein the acid rechargeable cell unit has an electrical potential of about 90 to 110% of the alkaline rechargeable cell unit, and the acid rechargeable cell unit comprises about 90 to 110% of the alkaline rechargeable cell unit, Have the capacity of;
And a resonance damping effect is calculated when the electrical potential balance between the acid rechargeable cell unit and the alkaline rechargeable cell unit is automatically maintained
And a damping function of the acid / alkali hybrid resonance battery device. The method according to claim 1,
The acid rechargeable cell is a lithium iron phosphate (LFP) acid rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device. The method according to claim 1,
The alkaline rechargeable cell is a nickel-zinc alkaline rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device. The method according to claim 1,
Wherein the acid rechargeable cell unit is composed of one acid rechargeable cell of 3.2 to 3.6 V and the alkaline rechargeable cell unit is composed of two alkali rechargeable cells of 1.6 to 1.8 V, The acid rechargeable cell has a capacity of about 90 to 110% of the alkaline rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device. The method according to claim 1,
Wherein the acid rechargeable cell unit is composed of two acid-rechargeable cells of 3.2 to 3.6 V connected in parallel, and the alkaline rechargeable cell unit is composed of two alkaline rechargeable cell units of 1.6 to 1.8 V, Wherein the acid rechargeable cell has a capacity of about 45 to 55% of the alkaline rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device. An acid / alkali hybrid resonance battery device having a damping function,
An acid rechargeable cell unit and an alkaline rechargeable cell unit electrically connected in parallel;
Wherein said acid rechargeable cell unit comprises at least one acid rechargeable cell, said alkaline rechargeable cell unit comprising at least one alkaline rechargeible cell;
When there is at least one alkaline rechargeable cell in the alkaline rechargeable cell unit, the alkaline rechargeable cell is connected in series;
Wherein the acid rechargeable cell unit has an electrical potential of about 90 to 110% of the alkaline rechargeable cell unit, and the acid rechargeable cell unit comprises about 90 to 110% of the alkaline rechargeable cell unit, Have the capacity of;
And a resonance damping effect is calculated when the electrical potential balance between the acid rechargeable cell unit and the alkaline rechargeable cell unit is automatically maintained
And a damping function of the acid / alkali hybrid resonance battery device. The method of claim 6,
The acid rechargeable cell is a lithium iron phosphate (LFP) acid rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device. The method of claim 6,
The alkaline rechargeable cell is a nickel-zinc alkaline rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device. The method of claim 6,
Wherein the acid rechargeable cell unit is composed of one acid rechargeable cell of 3.2 to 3.6 V and the alkaline rechargeable cell unit is composed of two 1.6 to 1.8 V alkaline rechargeible cells, The rechargeable cell has a capacity of about 90 to 110% of the alkaline rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device. The method of claim 6,
Wherein the acid rechargeable cell unit is composed of two acid-rechargeable cells of 3.2 to 3.6 V connected in parallel, and the alkaline rechargeable cell unit is composed of two alkaline rechargeable cell units of 1.6 to 1.8 V, Wherein the acid rechargeable cell has a capacity of about 45 to 55% of the alkaline rechargeable cell
And a damping function of the acid / alkali hybrid resonance battery device.

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