TWI539651B - Non-stationary seawater battery - Google Patents

Description

Non-fixed seawater battery

The invention relates to a seawater battery, in particular to a non-fixed seawater battery.

With the continuous increase of the global population and the advancement of science and technology, people's demand for energy is rising. Traditional fossil energy sources such as oil and coal are gradually in short supply. Therefore, renewable energy is gradually gaining attention, and because seawater accounts for about 100% of the earth's surface. With an area of 70%, the use of seawater to generate electricity has also become a development priority.

The way of using seawater to generate electricity is mainly tidal power generation, seawater temperature difference power generation, and seawater batteries. Among them, seawater batteries use seawater as an electrolyte, so that the electrodes can be immersed in seawater to generate electricity, which makes them particularly attractive for applications. In order to obtain greater power output, most of the applications are to design a plurality of seawater batteries in a series or parallel configuration, such as the "magnesium seawater battery" of the Chinese Patent No. CN 1543001, which includes an anode, a plurality of parallel An inert cathode, a plurality of battery frames, and a net surrounding the anode, the battery frames are evenly disposed on the net, and the inert cathodes are disposed on the battery frame adjacent to one end of the anode, when the seawater Power is generated by contact with the anode and the inert cathodes.

However, in order to keep the anode at a distance from the inert cathodes, it is necessary to provide the battery frames to fix the inert cathodes, so that the structure is complicated, and the anode and the inert cathodes are not easily replaced. Therefore, how to solve the seawater The problem of complicated battery assembly structure and difficulty in replacing the electrodes is a major issue.

The main object of the present invention is to solve the problem that the seawater battery assembly structure is complicated and the electrodes are not easily replaced.

In order to achieve the above object, the present invention provides a non-fixed seawater battery, comprising a first battery, a second battery disposed on the first battery, and a conductive component, the first battery including a first cavity, and a first battery a first seawater electrolyte disposed in the first tank and a first electrode assembly in contact with the first seawater solution, the first electrode assembly including a first anode disposed at a bottom of the first tank And a first cathode spaced apart from the first anode and suspended on the first seawater solution, the second battery includes a second tank body, a second seawater electrolyte contained in the second tank body, and a second electrode assembly in contact with the second seawater solution, the second electrode assembly includes a second anode disposed at a bottom of the second tank body and a distance from the second anode and suspended in the second seawater a second cathode on the electrolyte, the conductive component being electrically connected to the first electrode component and the second electrode component.

In summary, the present invention has the following features:

1. The first anode and the second anode are disposed at the bottom of the first tank and the second tank, and the first cathode and the second cathode are suspended in the first seawater solution. The second seawater electrolyte prevents the first anode from coming into contact with the first cathode and the second anode contacting the second cathode to cause a short circuit.

2. The first anode and the second anode need to be disposed at the bottom of the first tank body and the second tank body, so that the first cathode and the second cathode are randomly suspended, thereby reducing the complexity of the structure. Degree and manufacturing cost.

3. It is only necessary to re-inject the new first anode and the second anode, that is, to continuously generate electricity, and thus has the advantage of being easily replaced.

The detailed description and technical contents of the present invention will now be described as follows:

Please refer to FIG. 1 for a schematic cross-sectional view of a preferred embodiment of the present invention. The present invention is a non-stationary seawater battery, comprising a first battery 10, a second battery 20 disposed on the first battery 10, and a conductive component 30. The first battery 10 includes a first slot body 11, a first seawater electrolyte 12 and a first electrode assembly 13 , the first seawater electrolyte 12 is received in the first tank body 11 , the first electrode assembly 13 is in contact with the first seawater electrolyte 12 , and The first battery 131 disposed at the bottom of the first tank body 11 and the first cathode 132 spaced apart from the first anode 131 and suspended on the first seawater solution 12, the second battery 20 includes a second tank body 21, a second seawater solution 22, and a second electrode assembly 23, the second seawater solution 22 is received in the second tank body 21, the second electrode assembly 23 and the second seawater The electrolyte 22 is in contact with and includes a second anode 231 disposed at the bottom of the second tank 21 and a second cathode 232 spaced from the second anode 231 and suspended on the second seawater solution 22, the conductive The component 30 is electrically connected to the first electrode assembly 13 and the second electrode group Item 23.

The material of the first cathode 132 and the second cathode 232 may be carbon materials such as carbon, graphite thin, carbon black, carbon nanotubes or carbon fibers, and has a multi-porosity characteristic, so that the gas can be filled in the pores. The first cathode 132 and the second cathode 232 may have a thickness of between 1 mm (mm) and 10 mm (mm). Preferably, between 3 mm (mm) and 10 mm (mm), and the material of the first anode 131 and the second anode 231 may be an alloy formed of aluminum, magnesium, and a combination thereof.

Therefore, by disposing the first anode 131 and the second anode 231 at the bottom of the first tank body 11 and the second tank body 21, the first anode 131 can be prevented from being suspended in the first seawater electrolysis. The first cathode 132 on the liquid 12 contacts and prevents the second anode 231 from coming into contact with the second cathode 232 suspended on the second seawater solution 22 to cause a short circuit, and since only the first An anode 131 and the second anode 231 are respectively disposed at the bottoms of the first tank body 11 and the second tank body 21, and the positions of the first cathode 132 and the second cathode 232 are not required, and the structure can be reduced. Complexity and manufacturing costs.

In this embodiment, the first through hole 40 is disposed on a side of the first groove body 11, and the second hole 41 is disposed on a side of the second groove body 21, and the first hole is formed. The second through hole 41 is electrically connected to the second cathode 232, and the second anode 231 is electrically connected to the first cathode 132. A load 80 is connected in series between the first anode 131 and the second cathode 232 to form a battery series structure, so that the output voltage is increased, but a parallel structure can also be formed, which is not limited to the example of the embodiment.

The first battery 10 further includes a first input port 14 disposed on a side of the first slot 11 for inputting the first seawater solution 12 and a side disposed on the side of the first slot 11 The first output port 15 for outputting the first seawater electrolyte 12, and in the embodiment, the first input port 14 and the first output port 15 are disposed on opposite sides of the first battery 10, but can be matched The second battery 20 further includes a side disposed on the side of the second tank 21 for inputting the second seawater electrolyte 22, which is not limited thereto. a second input port 24 and a second output port 25 disposed on a side of the second tank body 21 for outputting the second seawater solution 22, and similarly, the second input port 24 and the second output port 25 The location can also be set to match the needs of the user. The first seawater solution 12 in the first tank body 11 and the second seawater electrolyte 22 can be maintained by the continuous inflow and outflow of the first seawater solution 12 and the second seawater solution 22 . The ion concentration in the second tank 21 stabilizes the generated current.

After the discharge, the first anode 131 and the second anode 231 react with the first seawater solution 12 and the second seawater solution 22 to generate by-products, and the by-products are flowed. A seawater electrolyte 12, the second seawater electrolyte 22 is carried away, and finally, after the first anode 131 and the second anode 231 are exhausted, the old first anode 131 and the second anode 231 are taken out. Then, the new first anode 131 and the second anode 231 are newly reintroduced, that is, power generation can be continued, and thus there is an advantage that it is easy to replace.

In summary, the present invention has the following features:

1. The first anode and the first suspension suspended on the first seawater solution are prevented by the first anode and the second anode being disposed at the bottom of the first tank body and the second tank body. A problem occurs when a cathode touches and prevents the second anode from coming into contact with the second cathode suspended on the second seawater solution.

Secondly, the first anode and the second anode need to be disposed at the bottom of the first tank body and the second tank body, and the position of the first cathode and the second cathode need not be provided, and the structure can be reduced. Complexity and manufacturing costs.

3. After the first anode and the second anode are exhausted, the power generation can be continued as long as the new first anode and the second anode are newly reintroduced, so that there is an advantage that the replacement is easy.

4. The first seawater electrolyte and the second seawater electrolyte are continuously flowed in and out by the first input port, the first output port, the second input port, and the second output port. The ion concentration of the first seawater solution in the first tank and the second seawater solution in the second tank is maintained to stabilize the generated current.

The present invention has been described in detail above, but the foregoing is only a preferred embodiment of the present invention, and is not intended to limit the scope of the invention. That is, the equivalent changes and modifications made by the scope of the present application should remain within the scope of the patent of the present invention.

10‧‧‧First battery
11‧‧‧ first trough
12‧‧‧First seawater electrolyte
13‧‧‧First electrode assembly
131‧‧‧First anode
132‧‧‧first cathode
14‧‧‧ first input
15‧‧‧ first output
20‧‧‧Second battery
21‧‧‧Second trough
22‧‧‧Second seawater electrolyte
23‧‧‧Second electrode assembly
231‧‧‧Second anode
232‧‧‧second cathode
24‧‧‧second input
25‧‧‧second output
30‧‧‧ Conductive components
40‧‧‧First perforation
41‧‧‧Second perforation
80‧‧‧load

1 is a schematic cross-sectional view of a preferred embodiment of the present invention.

10‧‧‧First battery

11‧‧‧ first trough

12‧‧‧First seawater electrolyte

13‧‧‧First electrode assembly

131‧‧‧First anode

132‧‧‧first cathode

14‧‧‧ first input

15‧‧‧ first output

20‧‧‧Second battery

21‧‧‧Second trough

22‧‧‧Second seawater electrolyte

23‧‧‧Second electrode assembly

231‧‧‧Second anode

232‧‧‧second cathode

24‧‧‧second input

25‧‧‧second output

30‧‧‧ Conductive components

40‧‧‧First perforation

41‧‧‧Second perforation

80‧‧‧load

Claims (10)

A non-fixed seawater battery includes: a first battery, a first tank body, a first seawater solution contained in the first tank body, and a first contact with the first seawater electrolyte An electrode assembly, the first electrode assembly includes a first anode disposed at a bottom of the first tank body and a first cathode spaced apart from the first anode and suspended on the first seawater solution; a second battery on the first battery, comprising a second tank body, a second seawater electrolyte contained in the second tank body, and a second electrode assembly in contact with the second seawater electrolyte, the second The electrode assembly includes a second anode disposed at a bottom of the second tank body and a second cathode spaced apart from the second anode and suspended on the second seawater electrolyte; and a conductive component electrically conductive Connected to the first electrode assembly and the second electrode assembly. The non-fixed seawater battery according to claim 1, wherein the material of the first cathode and the second cathode is selected from the group consisting of carbon, graphite thin, carbon black, carbon nanotubes, carbon fibers, and combinations thereof. Group. The non-fixed seawater battery of claim 1, wherein the material of the first anode and the second anode is selected from the group consisting of aluminum, magnesium, and combinations thereof. The non-stationary seawater battery of claim 1, wherein the first battery further comprises a first input port disposed on a side of the first tank for inputting the first seawater solution, and a first input port a first output port disposed on a side of the first tank for outputting the first seawater solution. The non-fixed seawater battery of claim 1, wherein the second battery further comprises a first side disposed on the side of the second tank for inputting the second seawater electrolyte a two-input port and a second output port disposed on a side of the second trough body for outputting the second seawater solution. The non-fixed seawater battery of claim 1, further comprising a first perforation disposed on a side of the first trough body for the conductive component to pass through. The non-fixed seawater battery of claim 1, further comprising a second perforation disposed on a side of the second trough for the conductive component to pass through. The non-fixed seawater battery of claim 1, wherein the first cathode and the second cathode have a thickness of between 1 mm and 10 mm. The non-fixed seawater battery of claim 1, wherein the first cathode and the second cathode have a thickness of between 3 mm and 10 mm. The non-fixed seawater battery according to claim 1, wherein a load is connected in series between the first anode and the second cathode.