TWI843077B - Box type seawater power generation system - Google Patents

Abstract

The present invention relates to a box-type seawater power generation system. The present invention uses two electrodes made of conductive plastic material. After the box is filled with seawater, the two electrodes and the seawater form a voltaic cell to generate electricity. In this way, in addition to being installed in a location that is not affected by the environment, the characteristics of plastic are used to reduce the manufacturing cost of the entire electrode. At the same time, in the process of replacing electrodes, the plastic is lighter in weight, which is conducive to the replacement operation, making the present invention more convenient to use.

Description

Box-type seawater power generation system

The present invention relates to an electric power system, in particular to a box-type seawater power generation system.

Please refer to Taiwan Certificate No. M577452 "Seawater Power Generation Device", the abstract of which states: "It includes: an inlet channel having a first inlet end and a first outlet end, the first inlet end being arranged below the sea level to allow seawater to flow into the inlet channel, the inlet channel extending downward from the first inlet end to the first outlet end at a predetermined angle and being provided with at least one water truck; the inlet channel is connected to a hydroelectric power generation module, the hydroelectric power generation module being located about 4 00 to 500 meters; and an outlet, one end of which is connected to the hydropower module, and the other end of which discharges seawater to the ground level. The outlet can be extended upward in a stepped manner and equipped with a water wheel and a winch to raise the seawater to the other end, or the diameter of the outlet gradually decreases from one end connected to the hydropower module to the other end; the third outlet can be directly discharged or a seawater aquaculture facility. This creation can be set up in an underground factory. ".

Although the patent has the advantages described in its specification, the actual implementation of the patent will cause problems such as large scale, which will greatly increase the overall power generation cost. Therefore, the inventor believes that there is a need for improvement and has begun to think about how to overcome the above problems.

In view of the deficiencies of the prior art, the inventors of the present invention provide a solution, which is related to a box-type seawater power generation system, including:

One box:

The interior of the box can be used to hold seawater. The surrounding side wall of the box is made of conductive plastic to serve as a first electrode. A second electrode is provided inside the box, and the second electrode is also made of conductive plastic.

1. Power module:

The power module is electrically connected to the first electrode and the second electrode respectively, and the power module can be electrically connected to a power storage unit or a power supply network.

The present invention mainly provides a more convenient power generation system. Just pour seawater into the box, and use the first electrode, the second electrode, the power module and the seawater to form a voltaic battery, so that electricity can be generated. At the same time, the first electrode and the second electrode are made of conductive plastic, so that the overall weight and manufacturing cost can be greatly reduced, which is convenient for the transportation and construction of the present invention, and is convenient for replacing the first electrode and the second electrode.

1: Cabinet

11: First electrode

111: Plastic board

112: Conductive layer

12: Second electrode

13: Inner shell

131: Space

132: Water outlet

133: Water inlet

14: Inner shell

141: Diversion port

2: Power module

The first figure is a schematic diagram of an embodiment of the present invention

The second figure is a schematic diagram of the second embodiment of the present invention

The following is an explanation of the structure, features and implementation examples of the invention with the help of diagrams, so that the examiner can have a deeper understanding of the invention.

Please refer to the first figure, the invention is about a box-type seawater power generation system, including:

One box (1):

Please refer to the first figure. The interior of the box (1) can be used to contain seawater. The surrounding side wall of the box (1) is made of conductive plastic to serve as a first electrode (11). A second electrode (12) is provided inside the box (1). The first electrode (11), the second electrode (12), and the seawater together define a voltaic cell, so that the present invention can generate electricity. The above-mentioned conductive plastic can be implemented as follows: (i) as shown in the second figure, the conductive plastic includes a plastic plate (111), a conductive layer (112) is set on the outer side of the plastic plate (111), and the conductive layer (112) is preferably a metal layer, for example, a layer of zinc or copper is electroplated on the surface of the plastic plate (111) as the conductive layer (112), so as to use the conductive layer (112) as an electrode. It should be noted that in this embodiment, the activity of the first electrode (11) and the second electrode (12) is preferably different. (2) The conductive plastic is a conductive polymer, such as polyacetylene (PAC), polyphenylacetylene (PPV), polyaniline (PANI), or poly(p-phenylene sulfide) (PPS). In addition, the conductive plastic can also be made of PVC raw materials as the base material, and carbon black, metal fiber, permanent antistatic masterbatch, etc. are added to form a conductive antistatic PVC, which can achieve antistatic, static dissipation, conductivity and electromagnetic interference (EMI) shielding functions. The conductive antistatic PVC has a wide hardness variation range, high mechanical strength, good printing and welding properties, flame retardancy, low water absorption and air permeability, good chemical corrosion resistance, and resistance to most inorganic acids, most organic solvents and inorganic salts. In addition, the above PVC can also be replaced by PVC, PE, PVDF, and ultra-fine carbon black can be used to make its conductivity reach 10 to the third power Ohm, and the metal fiber is preferably in powder state when added.

Since seawater is highly corrosive, when the first electrode (11) and the second electrode (12) are made of metal, they are not only very susceptible to seawater corrosion, but also difficult to replace due to their excessive weight. Therefore, the inventors have changed the materials of the first electrode (11) and the second electrode (12) to conductive plastic to address this shortcoming. The implementation of the conductive plastic is the same as above and will not be repeated.

Thus, the present invention utilizes the characteristic that the weight of plastic is lower than that of metal, greatly reduces the difficulty of replacing the electrode, and also has the advantage of reducing the overall manufacturing cost. When the electrode is made of metal material, the electricity generation effect is located on the metal surface. Therefore, one implementation of the present invention is to retain the surface as metal as the conductive layer (112), and replace the inside with the plastic plate (111), so that the conductive layer (112) is set on the outer side of the plastic plate (111). In this way, the electrode does not need to be made of metal as a whole, as long as the surface is metal and can be used as a conductor, thereby reducing the overall weight and manufacturing cost, making the replacement of the electrode more convenient, and also making the present invention convenient for installation and installation. It is also worth mentioning that the same effect is achieved when the first electrode (11) and the second electrode (12) are conductive polymers.

In addition, another embodiment of the present invention is that the housing (1) includes an inner shell (13) and an outer shell (14), the inner shell (13) has a space (131) inside for accommodating seawater, and the inner shell (13) is provided with a water outlet (132) at the bottom of the circumferential side, and the inner shell (13) is provided with a water inlet (133) above the water outlet (132), and the circumferential side wall of the inner shell (13) is the inner shell (14). The first electrode (11) and the second electrode (12) are arranged in the space (131); the outer shell (14) is sleeved on the outer side of the inner shell (13) so that the outer shell (14) can slide along the outer side of the inner shell (13); a guide port (141) is arranged on the circumferential side of the outer shell (14); the guide port (141) can be operatively connected to the water outlet (132) or the water inlet (133). In this way, when the seawater inside is to be replaced, the outer shell (14) can be pulled down to connect the water outlet (132) with the diversion port (141) to easily discharge the seawater. After the seawater is discharged, the outer shell (14) must be pulled up to connect the water inlet (133) with the diversion port (141), and then the seawater can be injected into the space (131) to complete the overall seawater replacement process.

A power module (2):

The power module (2) is electrically connected to the first electrode (11) and the second electrode (12), and the power module (2) can be electrically connected to a storage unit or a power supply network to transmit the generated power to the power supply network for use or to the storage unit for storage of electric energy. The power module (2) preferably has a power regulation function (such as step-up and step-down, three-phase current regulation, etc.), and the generated power is first regulated before being output.

The main features of the present invention are: utilizing the properties of the conductive plastic to significantly reduce the overall weight, especially when the first electrode (11) and the second electrode (12) need to be replaced, the overall replacement difficulty and replacement cost can be reduced, and the power generation is not affected by the environment and location, and through large-scale installation, the present invention has a very good power generation capacity.

In summary, the invention is indeed industrially applicable, has not been published or publicly used before the application, is not known to the public, and is non-obvious, meeting the patent requirements. Therefore, a patent application is filed in accordance with the law.

However, the above is a better example of the industrial implementation of the invention. All equivalent changes made within the scope of the patent application for the invention are within the scope of the subject matter of this case.

1: Cabinet

11: First electrode

12: Second electrode

13: Inner shell

131: Space

132: Water outlet

133: Water inlet

14: Inner shell

141: Diversion port

2: Power module

Claims (4)

A box-type seawater power generation system includes: a box body: the inside can be used to contain seawater, the surrounding side wall of the box body is made of conductive plastic to serve as a first electrode, and a second electrode is arranged inside the box body; the activity of the first electrode and the second electrode is different; an electric power module: electrically connected to the first electrode and the second electrode respectively, and the electric power module can be electrically connected to a storage unit or a power supply network. As described in item 1 of the patent application scope, the box-type seawater power generation system, wherein the box includes an inner shell and an outer shell, the inner shell has a space inside for accommodating seawater, and the inner shell is provided with a water outlet at the bottom of the circumferential side, and the inner shell is provided with a water inlet above the water outlet, the circumferential side wall of the inner shell is the first electrode, and the second electrode is arranged in the space; the outer shell is sleeved on the outer side of the inner shell so that the outer shell can slide along the outer side of the inner shell, and a diversion port is provided on the circumferential side of the outer shell, and the diversion port can be operably connected with the water outlet or the water inlet. As described in item 1 or 2 of the patent application scope, the box-type seawater power generation system, wherein the conductive plastic includes a plastic, and a conductive layer is sheathed on the outer side of the plastic. As described in item 1 or 2 of the patent application scope, the box-type seawater power generation system, wherein the conductive plastic is a conductive polymer.

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