KR102512956B1 - Self-rechargeable super capacitor - Google Patents

Abstract

The supercapacitor according to the present embodiment includes a thermal ionic electrolyte gel; a supercapacitor electrolyte gel adjacent to the thermoelectric electrolyte; a grid electrode electrically connected with the supercapacitor electrolyte; It includes a plate electrode electrically connected to the supercapacitor electrolyte gel, wherein the plate electrode is electrically connected to the grid electrode so that the thermoelectric electrolyte gel charges the supercapacitor, and the plate electrode and the grid electrode are electrically insulated so that the supercapacitor discharges. do.

Description

Self-rechargeable super capacitor {SELF-RECHARGEABLE SUPER CAPACITOR}

The present technology relates to self-charging supercapacitors.

In the case of conventional MEMS switches, it was common to induce switching by applying a voltage. A plurality of switches controlled the switch by applying a voltage provided from a power source.

In the case of conventional thermally charged supercapacitors, the voltage of the thermoelectric element does not drop when thermal energy is continuously supplied. Therefore, it was impossible to discharge the supercapacitor, and the heat charging effect and the energy storage cycle were limited. Practically, it was necessary to lower the temperature for discharge, but the use of a heat sink not only complicates the structure but also restricts the useable temperature.

One of the problems to be solved by the present technology is to solve the above-mentioned difficulties of the prior art. That is, providing a supercapacitor capable of discharging without a heat sink is one of the problems to be solved by the present technology.

The supercapacitor according to the present embodiment includes a thermal ionic electrolyte gel; a supercapacitor electrolyte gel adjacent to the thermoelectric electrolyte; a grid electrode electrically connected with the supercapacitor electrolyte; It includes a plate electrode electrically connected to the supercapacitor electrolyte gel, wherein the plate electrode is electrically connected to the grid electrode so that the thermoelectric electrolyte gel charges the supercapacitor, and the plate electrode and the grid electrode are electrically insulated so that the supercapacitor discharges. do.

According to one aspect of this embodiment, the plate electrode is in the form of a leaf spring.

According to one aspect of this embodiment, the plate spring is electrically connected to the grid electrode when the electrostatic attraction formed between the thermoelectric electrolyte gel and the grid electrode exceeds the restoring force of the plate spring.

According to one aspect of the present embodiment, the thermoelectric electrolyte gel is an electrolyte gel that causes a Soret effect, Co _X M _1-X O ₂ , Na _X Co _X O ₄ , Ba _1-X Sr _X PbO ₃ A supercapacitor.

According to one aspect of the present embodiment, an electrolyte gel that causes a Seebeck effect, Co(OH) ₂ , Ni(OH) ₂ A supercapacitor of any one.

According to one aspect of this embodiment, the supercapacitor electrolyte gel is any one of Co(OH) ₂ and Ni(OH) ₂ .

According to the present embodiment, the supercapacitor can provide energy to the load side without a heat sink required in the prior art, so the structure is simple and can be manufactured at low cost.

1 is a perspective view showing the outline of a self-charging capable supercapacitor 10 according to the present embodiment.
2 is a view schematically showing a cross section of the supercapacitor 10 according to the present embodiment.
FIG. 3(a) is a diagram schematically showing when the grid electrode and the plate electrode are electrically connected so that the thermoelectric electrolyte gel charges the supercapacitor electrolyte gel, and FIG. 3(b) shows the supercapacitor electrolyte gel discharging. It is a plan view schematically showing the time when the supercapacitor 10 according to this embodiment is viewed from the plate electrode side.

Hereinafter, an embodiment of the present invention will be described in detail through exemplary drawings. 1 is a perspective view showing an outline of a self-charging capable supercapacitor 10 according to the present embodiment. Referring to FIG. 1, a self-rechargeable supercapacitor 10 according to this embodiment includes a thermal ionic electrolyte gel 220 and a supercapacitor electrolyte gel 210 adjacent to the thermoelectric electrolyte. It includes a grid electrode 200 and a plate electrode 100 electrically connected to the supercapacitor electrolyte, and the plate electrode 100 is electrically connected to the grid electrode 200 so that the thermoelectric electrolyte gel forms the supercapacitor. After charging, the plate electrode and the grid electrode are electrically insulated so that the supercapacitor discharges.

The thermoelectric electrolyte gel 220 is an electrolyte that generates a thermoelectric phenomenon and forms electrical energy from a temperature difference. In order for the thermoelectric electrolyte gel 220 to form electrical energy, there must be a temperature difference.

The thermoelectric electrolyte gel 220 must be positioned between the high temperature part Thot and the low temperature part Tcold and operates based on a double channel structure connecting them. The double channel is largely divided into N-type and P-type. In the N-type channel, the electric field is formed from the low-temperature part to the high-temperature part, and in the P-type channel, the electric field is formed from the high-temperature part to the low-temperature part, and the current also flows in the same direction as the electric field. At this time, looking at the carrier gradient, carriers are formed in the high-temperature portion of the N-type channel and phonons are formed in the high-temperature portion of the P-type channel.

The thermoelectric electrolyte gel 220 may be, for example, an electrolyte material that forms electrical energy by the Seebeck Effect, and current is formed due to the formation of electrons, holes, and phonons based on the Seebeck effect due to temperature asymmetry. . As described above, energy can be produced only when there is a temperature gradient, and since the voltage of the thermoelectric element does not decrease when the temperature gradient is maintained, discharge is required. In one embodiment, the electrolyte material that forms electrical energy by the Seebeck effect may be Co(OH) ₂ or Ni(OH) ₂ .

As another example, the thermoelectric electrolyte gel 220 may be a thermoelectric electrolyte gel based on the Soret Effect. A thermoelectric electrolyte based on the Soret effect generates electrical energy using an ion gradient formed by a temperature gradient. That is, when a temperature gradient is formed, voltage is formed while ions move, and it can be referred to as a voltage inducer. Then, discharging is performed by consuming the formed electrical energy (voltage). In an embodiment, the electrolyte material generating electrical energy by the Soret effect may be Co _X M _1-X O ₂ , Na _X Co _X O ₄ , or Ba _1-X Sr _X PbO ₃ .

As described above, the thermoelectric electrolyte gel 220 must remove the temperature difference to complete the charge/discharge cycle, and for this, a heat sink is required. However, as will be described later, according to the present embodiment, charging and discharging can be performed without a heat sink.

The supercapacitor electrolyte gel 210 may be an electrolyte material that forms an electric double layer (EDLC) and uses the same. Unlike conventional capacitors, this is a type in which positive ions and negative ions are formed in an electrical double layer to store electrical energy. This type of electrolyte material has a very small separation distance D of the electric double layer, and can store large energy with rapid charging and discharging. Electrolyte materials of this type may be Co(OH) ₂ , Ni(OH) ₂ .

As another example, the thermoelectric electrolyte gel 220 may be a pseudo-type electrolyte. In the pseudo-type electrolyte, ions move through the electrolyte, and the ions that move exist by being combined/decomposed with active materials present at the positive and negative ends. That is, it stores electrical energy by oxidation-reduction reaction. Electrolyte materials of this type may be Co _X M _1-X O ₂ , Na _X Co _X O ₄ , Ba _1-X Sr _X PbO ₃ .

Next, the operation of the supercapacitor 10 according to the present embodiment will be described with reference to FIGS. 1 to 3 . 2 is a diagram schematically showing a cross-section of the supercapacitor 10 according to this embodiment, and FIG. 3(a) is a grid electrode and a plate electrode electrically connected to charge the supercapacitor electrolyte gel with the thermoelectric electrolyte gel. 3(b) is a diagram schematically showing the time when the supercapacitor electrolyte gel is discharged, and the supercapacitor 10 according to this embodiment is installed on the plate electrode side. This is a flat view. 1 to 3, the grid electrode 200 is electrically connected to the supercapacitor electrolyte gel 210.

The plate electrode 100 may be a plate spring positioned above the supercapacitor 10 , both ends fixed thereto, and deformed by electrical attraction of the thermoelectric electrolyte 220 . In the illustrated embodiment, the plate electrode 100 may be modeled as a spring whose spring constant value is k.

When a temperature difference is provided to the thermoelectric electrolyte gel 220 and energy is charged, an electrostatic attraction occurs between the thermoelectric electrolyte gel 220 and the grid electrode. When the electrostatic attraction is greater than the restoration of the plate electrode 100, the plate electrode is deformed and electrically connected to the grid electrode.

Therefore, the thermoelectric electrolyte 220 and the supercapacitor electrolyte gel 210 are electrically connected to each other through the plate electrode 100 and the grid electrode 200, and the electrical energy formed by the thermoelectric electrolyte gel 220 is transferred to the supercapacitor electrolyte. The gel 210 is filled. However, the electrical connection between the super peracitor electrolyte gel 210 and LOAD is cut off.

However, when the electrical energy formed by the thermoelectric electrolyte gel 220 is transferred to the supercapacitor electrolyte gel 210, the electrostatic attraction is reduced, and the plate electrode 100 is restored to its original state. Accordingly, the plate electrode 100 is positioned in its original state, and the grid electrode 200 can discharge electrical energy charged in the LOAD.

As described above, the supercapacitor according to the present embodiment can discharge electrical energy to a load without a heat sink, and thus has a simple structure and economical manufacturing cost.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention.

The embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments.

The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

The present invention designed and manufactured a MEMS switch to overcome the limitations of the existing heat sink and heat dissipation structure for voltage control of thermal charging capacitors.

10: super capacitor 100: plate electrode
200: grid electrode 210: supercapacitor electrolyte gel
220: Thermal ionic electrolyte gel

Claims (6)

thermal ionic electrolyte gels;
a supercapacitor electrolyte gel adjacent to the thermoelectric electrolyte;
a grid electrode electrically connected to the supercapacitor electrolyte;
A plate electrode electrically connected to the supercapacitor electrolyte gel,
The plate electrode is electrically connected to the grid electrode so that the thermoelectric electrolyte gel charges the supercapacitor;
A supercapacitor in which the plate electrode and the grid electrode are electrically insulated so that the supercapacitor discharges. According to claim 1,
The plate electrode is
A supercapacitor in the form of a leaf spring. According to claim 2,
When the electrostatic attraction formed between the thermoelectric electrolyte gel and the grid electrode exceeds the restoring force of the plate spring
A supercapacitor in which the plate spring is electrically connected to the grid electrode. According to claim 1,
The thermoelectric electrolyte gel is an electrolyte gel that causes a Soret effect,
Supercapacitors with Co _X M _1-X O ₂ , Na _X Co _X O ₄ , Ba _1-X Sr _X PbO ₃ .
According to claim 1,
The thermoelectric electrolyte gel is an electrolyte gel that causes the Seebeck effect,
A supercapacitor that is either Co(OH) ₂ or Ni(OH) ₂ .
According to claim 1,
The supercapacitor electrolyte gel is any one of Co(OH) ₂ and Ni(OH) ₂ Supercapacitor.

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