KR101002963B1 - Zinc-air fuel cell assembly - Google Patents

Abstract

PURPOSE: A zinc-air fuel cell assembly is provided to simplify a configuration for supplying fuel zinc into a reaction system and to maximize current collection efficiency and use efficiency of a battery. CONSTITUTION: A zinc-air fuel cell assembly includes: a negative electrode bag(10) with an accommodation space(12) in which zinc balls(20) are accommodated together with electrolyte; a current collector(14) for dividing the accommodation space of the negative electrode bag into a plurality of spaces and collecting electrons generated by the reaction of the zinc balls with oxygen; a housing(30) in which the negative electrode bag and current collector are arranged; and a pair of fuel supply ribs(40).

Description

Zinc-air fuel cell assembly

The present invention relates to a zinc-air fuel cell assembly, and more particularly to a zinc-air fuel cell that generates electricity by a reaction between zinc and oxygen in air. A zinc-air fuel cell assembly with an improved structure to simplify it.

Recently, electric vehicles, motorbikes, and electric buses, which do not generate smoke in accordance with environmental policies and green energy policies, which are trying to preserve nature, have become a hot topic.

The zinc-air fuel cell collects electrons generated by the reaction of zinc and oxygen in the air in the electrolyte (A) to generate electricity. In recent years, the zinc-air fuel cell uses a conventional fuel cell that generates electricity by using hydrogen generated from fuel. As a replacement fuel cell, development is being actively conducted.

 Such a zinc-air fuel cell has a simple structure of a reaction system for generating electrons, and thus, it is emerging to meet the development trend of an electric vehicle, which is intended to increase the efficiency of use by implementing a high capacity battery by reducing weight and reducing power consumption.

In particular, in the case of a zinc-air fuel cell, a plurality of cells forming a reaction system should be provided, and components for organic connection between the cells should be provided.

Therefore, the zinc-air fuel cell assembly having such a configuration should be developed to simplify the configuration and increase the battery use efficiency in order to comply with recent technical trends and policies.

The present invention has been made in view of the above necessity, and an object of the present invention is to provide a zinc-air fuel cell assembly which can achieve a simplified configuration.

Another object of the present invention is to provide a zinc-air fuel cell assembly that can increase the battery use efficiency.

The present invention for achieving the above object is a negative electrode bag having a receiving space that is accommodated with the zinc ball electrolyte; A current collector for partitioning a plurality of accommodating spaces of the cathode bag and collecting electrons generated by the reaction of the zinc balls and oxygen in the accommodating spaces; A housing in which the negative electrode bag and the current collector are disposed; And a pair of fuel supply ribs for supplying the zinc ball to the accommodation space, the fuel supply ribs being rotatably installed in the housing and having one side edges facing each other. When the gap is rotated to generate a gap between the edges, characterized in that the zinc ball is configured to be supplied to the receiving space through the gap.

The present invention includes a transport pipe for providing a circulation path of the electrolyte so that the electrolyte flowing out of the housing can be circulated to flow into the housing; It is preferable to further include a filter provided on the circulation path in order to filter the impurities contained in the electrolyte before the electrolyte flowing out of the housing flows back into the housing.

The present invention preferably further includes an inlet blower fan installed in the housing so as to force the air for reaction with the zinc ball into the housing.

Preferably, the present invention further includes a blower fan for discharging installed in the housing so as to forcibly discharge the air introduced into the housing.

According to the present invention, the accommodation space is divided into three spaces by the current collector, and in one of the three spaces, the opposite one edge of the pair of fuel supply ribs is inclined downward with respect to the other edge. The zinc ball is rotated so that the zinc ball is supplied, and the opposite side edges of the pair of fuel supply ribs are inclined upward with respect to the other edge in both spaces formed at both sides with a center space among the three spaces therebetween. It is preferable that the zinc ball is configured to be supplied by being rotated.

It is preferable that a vibrator is installed in the housing to generate sound wave vibrations in the electrolyte and to remove impurities adsorbed on the zinc balls.

The zinc-air fuel cell assembly according to the present invention having the configuration as described above is configured to selectively supply zinc balls to a plurality of spaces requiring zinc balls by forward and reverse rotation of a pair of fuel supply ribs. As a result, it is not necessary to provide a separate fuel supply device for supplying zinc balls to the plurality of spaces, respectively. As a result, by employing a pair of fuel supply ribs in the present invention, the present invention has the advantage of simplifying the configuration of a fuel supply device that must supply fuel to a plurality of spaces requiring zinc balls, respectively.

The present invention has the advantage that the current collector having a current collector function is formed to increase the contact area with the zinc ball, thereby maximizing the current collector efficiency to increase the battery use efficiency.

1 is a cross-sectional view of a zinc-air fuel cell according to an embodiment of the present invention.
Figure 2 is a perspective view of a reaction cell unit employed in one embodiment of the present invention.
3 and 4 is an operational state diagram of one embodiment of the present invention.

Hereinafter, a zinc-air fuel cell assembly according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a zinc-air fuel cell according to an embodiment of the present invention, Figure 2 is a perspective view of a reaction cell unit employed in one embodiment of the present invention, Figure 3 and Figure 4 is an operation of one embodiment of the present invention State diagram.

As shown in these drawings, the present invention is for supplying power to a motor that is a power source of an electric vehicle, the negative electrode pocket 10, the current collector 14, the housing 30 and a pair of fuel supply ribs ( 40).

The negative electrode bag 10 has an accommodating space 12 in which zinc balls 20 and electrolyte A react with oxygen in the air. Here, the zinc ball 20 has a spherical shape.

The zinc ball 20 performs a redox reaction with oxygen introduced from the outside in the electrolyte A, thereby producing zinc oxide while leaving electrons. The current collector 14 collects electrons generated by the reaction to generate electricity, and the generated electricity is stored in a battery (not shown).

As illustrated in FIG. 2, the current collector 14 includes a partition plate 14a that divides the accommodation space 12 into a large width, and extends from the partition plate 14a to extend the accommodation space 12. ) Is provided with a plurality of ribs 14b for dividing) into small widths. Each of the ribs 14b divides the space largely divided by the partition plate 14a, thereby partitioning the accommodation space 12 into a plurality. The partition plate 14a and the ribs 14b are preferably perpendicular to each other and are integrally formed.

In the current collector 14, the zinc balls 20 are disposed between the ribs 14b to increase the current collecting efficiency by increasing the contact area with the zinc balls 20. The material of the current collector 14 is a conductive material such as copper, brass, bronze, nickel, etc. to enable current collection, and is preferably plated with gold, silver, platinum, etc. in order to improve corrosion resistance and electronic current collecting capability. The current collector 14 has a plurality of holes through which the electrolyte A can pass, and the negative electrode bag 10 also has a plurality of holes for passing through the electrolyte A.

Meanwhile, in the present embodiment, the current collector 14 and the negative electrode bag 10 are integrally formed, but the present invention is not limited thereto. For example, the current collector 14 and the negative electrode bag 10 may be separately. It is also possible to be configured to be assembled after molding.

As described above, the present invention has the advantage that the current collector 14 having a current collector function is formed to increase the contact area with the zinc ball 20, thereby maximizing the current collector efficiency to increase the battery use efficiency. .

The present embodiment includes a case 16 coupled to the cathode bag 10 and a vibrator 18 installed inside the case 16.

The case 16 may communicate with the accommodation space 12 of the negative electrode bag 10 to accommodate the electrolyte A contained in the accommodation space 12 therein. Here, the internal space of the case 16 is called a communication space 22.

The vibrator 18 is disposed in the communication space 22 of the case 16 to generate sound wave vibrations, causing waves in the electrolyte A to absorb zinc oxide adsorbed on the zinc ball 20. It serves to desorb from (20). As a result, this embodiment has the advantage of increasing the reaction efficiency between the zinc ball 20 and oxygen.

In this embodiment, the receiving space 12 is partitioned into three spaces 12a and 12b by the current collector 14, as shown in FIG.

The fuel supply ribs 40 rotate in the housing 30 as shown in FIGS. 3 and 4 so that the zinc balls 20 can be smoothly supplied to the three spaces 12a and 12b. It is possible to install.

That is, when the zinc ball 20 is to be supplied to the space 12a located in the middle of the three spaces 12a and 12b, the fuel supply ribs 40 are rotated as shown in FIG. A gap is generated between one side edges of the fuel supply ribs 40 facing each other, and the zinc ball 20 is supplied to the center space 12a through the gap.

On the contrary, in the two spaces 12b positioned on both sides of the three spaces 12a and 12b with the center space 12a interposed therebetween, the pair of fuel supply ribs 40 face each other. One side edge is rotated so as to be inclined upward with respect to the other edge is supplied to each of the divided zinc balls 20.

As such, the present invention allows the zinc balls 20 to be selectively supplied to the plurality of spaces 12a and 12b where the zinc balls 20 are required by the forward and reverse rotation of the pair of fuel supply ribs 40. As a result, it is not necessary to provide a separate fuel supply device for supplying the zinc balls 20 to the plurality of spaces 12a and 12b, respectively. As a result, the pair of fuel supply ribs 40 are employed in the present invention, thereby simplifying the configuration of the fuel supply device that must supply fuel to the plurality of spaces 12a and 12b where the zinc balls 20 are required. You can do it.

Meanwhile, the negative electrode bag 10 and the current collector 14 are closed by the housing 30.

In this embodiment, the transport pipe 50 connected to the housing 30, the inlet blower fan 60, the outlet blower fan 70, and the path of the transport pipe 50 installed in the housing 30. The filter 80 provided in the phase is provided.

In addition, the liquid pump 90 provided on the circulation path of the transport pipe 50 so that the electrolyte filtered through the filter 80 may be introduced again into the housing 30 through the transport pipe 50. ). The liquid pump 90 includes a cylinder, a piston, and the like for pumping the electrolyte.

The cylinder and the piston are preferably made of a material having a high corrosion resistance such as PTFE (Polytetrafluoroethylene) because the electrolyte is a strong base material such as KOH, NaOH.

The transport pipe 50 provides a circulation path of the electrolyte A so that the electrolyte A flowing out of the housing 30 circulates and flows back into the housing 30 again, and the filter 80 is provided on the circulation path so that the impurities A contained in the electrolyte A are filtered before the electrolyte A flowing out of the housing 30 flows back into the housing 30 again. It plays a role.

As described above, the present embodiment includes a transport pipe 50 which provides a circulation path of the electrolyte A and a filter 80 for filtering the impurities B contained in the electrolyte A, thereby providing an electrolyte ( As can reduce the replacement and maintenance costs of A) has the advantage of increasing the efficiency of using the electrolyte (A).

In addition, the inlet blowing fan 60 serves to forcibly introduce air for reaction with the zinc ball 50 into the housing 30, and the outlet blowing fan 70 is the housing. (30) serves to forcibly discharge the air introduced into the interior.

In this embodiment having such a configuration, by adjusting the flow of air in the housing 30 by the inlet blower fan 60 and the exhaust blower fan 70, the zinc ball 20 and air It can increase the reaction efficiency of the liver, and has the advantage of improving the cooling efficiency of the heat generated in the housing (30).

As mentioned above, although preferred embodiment about this invention was described, this invention is not limited to the above-mentioned embodiment, It is defined by what was described in the claim, and it is clear that various deformation | transformation and adaptation are possible in the technical field to which this invention belongs. Do.

10: negative electrode pocket 12: accommodation space
12a: center space 12b: space on both sides
14: current collector 14a: compartment
14b: Rib 16: Case
18: Vibrator 20: Zinc Ball
22: communication space 30: housing
40: fuel supply rib 50: transport pipe
60: blowing fan for inflow 70: blowing fan for discharge
80: filter 90: liquid pump

Claims (6)

A cathode bag 10 in which zinc balls 20 are accommodated together with an electrolyte A;
The accommodating space 12 of the cathode bag 10 is divided into both spaces 12b formed at both sides with a center space 12a and a space 12a therebetween, and the space in the accommodation space 12 A current collector 14 for collecting electrons generated by the reaction between the zinc ball 20 and oxygen;
A housing 30 in which the negative electrode bag 10 and the current collector 14 are disposed therein; And
A pair of fuel supply ribs 40 for supplying the zinc ball 20 to the accommodation space 12, rotatably installed in the housing 30, and one side edges of which are disposed to face each other; With
In the center space 12a of the three spaces, one side edge of the pair of fuel supply ribs 40 is rotated to be inclined downward with respect to the other edge so that the zinc ball 20 is supplied.
In both spaces 12b formed on both sides of the three spaces with the center space 12a interposed therebetween, one side edge of the pair of fuel supply ribs 40 rotates to be inclined upward with respect to the other edge. Zinc-air fuel cell assembly, characterized in that configured to be supplied to the zinc ball (20). The method of claim 1,
A transport pipe (50) which provides a circulation path of the electrolyte (A) so that the electrolyte (A) flowing out of the housing (30) circulates and flows into the housing (30);
A filter provided on the circulation path to filter the impurities B contained in the electrolyte A before the electrolyte A flowing out of the housing 30 flows back into the housing 30 again. Zinc-air fuel cell assembly, characterized in that it further comprises (80). The method of claim 1,
And an inlet blower fan 60 installed in the housing 30 to force the air for reaction with the zinc ball 20 into the housing 30. Zinc-air fuel cell assembly. The method of claim 3,
Zinc-air fuel cell assembly, characterized in that it further comprises; a blowing fan (70) installed in the housing (30) so as to forcibly discharge the air introduced into the housing (30). The method of claim 1,
Zinc-air fuel cell assembly, characterized in that the oscillator 18 for removing the impurities adsorbed on the zinc ball 20 by generating a sound wave vibration in the electrolyte (A) inside the housing (30) . delete

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