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Overunity Machines Forum



Japanese Company Has A Car That Runs On Water.

Started by ResinRat2, June 13, 2008, 11:28:43 AM

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kavee


kavee

Detailed Description for the patent publication number JP2006-244714A (refer to the above image), as per translation provided by Japanese Patent Office. (I personally not responsible for the translation, thus not responsible of any damages caused by using this)....


QUOTE---

DETAILED DESCRIPTION [Detailed Description of the Invention]
[Field of the Invention]
[0001] This invention relates to the water energy system which can generate electricity in ordinary temperature atmosphere by using water as fuel.

[Background of the Invention]
[0002] Various kinds of fuel cells are proposed in the former. A fuel cell is a device which generates electric power using electrochemical reaction.
Although based also on the kind of material which constitutes the cell, various kinds of substances are used as fuel.
For example, an organic substance like methanol or HOARUMU aldehyde is used.
[0003] Here, in the general fuel cell, before supplying fuel to a fuel electrode directly so that hydrogen can be efficiently supplied to the fuel electrode, it is letting pass and reforming to the fuel reformer. As a system which supplies fuel to the fuel electrode of a cell directly, and oxidizes, the direct methanol type fuel cell is known, for example.

[Description of the Invention]
[Problem(s) to be Solved by the Invention]
[0004]There is a technical problem of this invention in proposing the water energy system which can generate electricity under ordinary temperature using pure water, without using fuel, such as methanol.

[Means for Solving the Problem]
[0005] In order to solve the above-mentioned technical problem, a water energy system of this invention, According to electrochemical reaction which carries out the placed opposite of a fuel electrode and the oxygen pole on both sides of an electrolyte, supplies pure water to said fuel electrode, supplies oxygen to said oxygen pole, and is generated in said fuel electrode and said oxygen pole. Make direct current power output from these poles, and platinum as said fuel electrode using what was supported to a sintered compact of zeolite, the Coral Sea sand, and particle powder of carbon black as said oxygen pole, It is characterized by using that with which a ruthenium was supported by sintered compact of zeolite and particle powder of carbon black.

[Effect of the Invention]
[0006] According to this invention person's experiment, in the water energy system by this invention, when pure water was directly supplied to the fuel electrode, oxidative degradation of the hydrogen contained there was carried out efficiently, and it was checked that power generation operation is efficiently performed under ordinary temperature. Therefore, according to this invention, the fuel cell system which can generate electricity efficiently with an easy mechanism can be realized like before, without using fuel gas, such as methanol.

[Best Mode of Carrying Out the Invention]
[0007] The embodiment of the water energy system which applied this invention to below with reference to drawings is described.
[0008] Drawing 1 is an outline lineblock diagram of the water energy system concerning this embodiment. The water energy systems 1 are water and a system which generates electricity according to the electrochemical reaction of a catalyst, and the fundamental composition of them is the same as that of the case of a general fuel cell.
[0009] As shown in a figure, the water energy system 1 sandwiches the catalyst 2, and many cells of composition of that the placed opposite of the fuel electrode 3 (anode) and the oxygen pole 4 (cathode) was carried out have structure connected to series. Only one cell is shown in the figure. The pure water 5 is directly supplied to the fuel electrode 3, and the hydrogen contained there is electrolyzed by a hydrogen ion and the minus electron according to a catalyst. Air is supplied to the oxygen pole 4 of another side from the exterior, the oxygen contained there carries out a reduction reaction to a hydrogen ion according to a catalyst, and water is generated. The generated water is circulated to the fuel electrode 3 side via an unillustrated recovery passage.
[0010] The fuel electrode 3 and the oxygen pole 4 are connected to the external load 8 via the leads 6 and 7 currently pulled out from them. The external load 8 is a motor, a lamp, etc. which are driven by a direct current. It is also possible to store the leads 6 and 7 in the rechargeable batteries 9, such as an electrical double layer capacitor, and to use them via the inverter 10 with this instead of the external load 8, as AC power supply which can supply exchange.
[0011] Here, in this example, that with which platinum was supported by the sintered compact of zeolite, the Coral Sea sand, and the particle powder of carbon black is used as the fuel electrode 3. That with which the ruthenium was supported by the sintered compact of zeolite and the particle powder of carbon black is used as the oxygen pole 4.
[0012] The power generation operation of the water energy system 1 of this composition is explained. If the pure water 5 is supplied to the fuel electrode 3, it will be electrolyzed, hydrogen and oxygen will be generated and hydrogen will be divided into a hydrogen ion and a minus electron according to electrochemical reaction. Since hydrogen emits electrons, this reaction is oxidation reaction. The produced hydrogen ion moves to the oxygen pole 4 through the catalyst 2. Although the catalyst 2 has ionic permeability, since it does not let an electron pass, a minus electron is taken out outside via the lead 6.
[0013] On the other hand, air is sent into the oxygen pole 4, the hydrogen ion to which the oxygen contained there is supplied through the catalyst 2, and the electron supplied via an external circuit carry out a reduction reaction, and water is generated. Thereby, power generation is performed.

[Brief Description of the Drawings]
[0014] [Drawing 1]It is an outline lineblock diagram of the water energy system which applied this invention.
[Description of Notations]
[0015] 1 Water energy system
2 Catalyst
3 Fuel electrode
4 Oxygen pole
5 Pure water
6 and 7 Lead
8 Load
9 Rechargeable battery
10 Inverter


--UNQUOTE

kavee


kavee

Translation provided by Japanese Patent office for the publication number JP2007-157405A


QUOTE---

[Detailed Description of the Invention]
[Field of the Invention]
[0001] This invention relates to the power generation system which can generate electricity in ordinary temperature atmosphere by using water as fuel.

[Background of the Invention]
[0002] Various kinds of fuel cells are proposed in the former. A fuel cell is a device which generates electric power using electrochemical reaction.
Although based also on the kind of material which constitutes the cell, various kinds of substances are used as fuel.
For example, an organic substance like methanol or HOARUMU aldehyde is used.
[0003] In the general fuel cell, before supplying fuel to a fuel electrode directly so that hydrogen can be efficiently supplied to the fuel electrode (anode), it is letting pass and reforming to the fuel reformer. As a system which supplies fuel to the fuel electrode of a cell directly, and oxidizes, the direct methanol type fuel cell is known, for example.

[Description of the Invention]
[Problem(s) to be Solved by the Invention]
[0004] There is a technical problem of this invention in proposing the power generation system which can generate electricity under ordinary temperature using pure water, without using fuel, such as methanol.
[Means for Solving the Problem]
[0005] In order to solve the above-mentioned technical problem, a power generation module of this invention, Having a collecting electrode plate of a couple, and a diaphragm of at least two sheets and an electrode joint plate of at least one sheet which are laminated among these collecting electrode plates, an electrode joint plate has composition that lamination adhesion of an anode lateral electrode board and the cathode lateral electrode board was carried out on both sides of an electrolyte membrane.
[0006] An anode side surface in which a pure water supply groove is formed as for said diaphragm, A cathode side surface in which an air supply slot is formed, and a peripheral end face in which an air intake is formed, It has a pure water supply hole penetrated to a thickness direction of the diaphragm concerned in a part from which it separated from a formation area of said pure water supply groove and said air supply slot, Said air intake is open for free passage into said air supply slot via an air duct formed in an inside of said diaphragm, and said pure water supply hole is open for free passage to said pure water supply groove via a pure water passage formed in an inside of said diaphragm.
[0007] To said electrode conjugate and said collecting electrode plate. A pure water supply hole penetrated to a thickness direction in a part corresponding to each is formed in each pure water supply hole of said diaphragm, respectively, and to said anode lateral electrode board of said electrode conjugate. Said diaphragm is laminated in the state where said anode side surface confronts each other, and said diaphragm is laminated by said cathode lateral electrode board in the state where said cathode side surface confronts each other.
[0008] In a power generation module of this composition, pure water supplied to a pure water supply hole of a diaphragm from the exterior is supplied to a pure water supply groove currently formed in that anode side surface through a pure water passage inside a diaphragm. Since an anode side surface stands face to face against an anode lateral electrode board of an electrode conjugate, pure water supplied to a pure water supply groove is supplied to an anode lateral electrode board. On the other hand, air introduced from an air intake of a diaphragm peripheral end face passes along an internal air duct, and is supplied to an air supply slot currently formed in a cathode side surface. Since a cathode side surface stands face to face against a cathode lateral electrode board of an electrode conjugate, air supplied to an air supply slot is supplied to a cathode lateral electrode board. As a result, a direct current which an electrode conjugate generated and generated according to electrochemical reaction generated between an anode lateral electrode laminated on both sides of an electrolyte membrane and a cathode lateral electrode is taken out from a collecting electrode plate.
[0009] Power generation capacity can be made to increase simply, when said electrode conjugate of two or more sheets sandwiched and carries out the series connection of said diaphragm.
[0010] What is necessary is just to laminate said electrode conjugate and said diaphragm, where a frame shape gasket is pinched in order to hold between said electrode conjugate and each diaphragm to a fluid-tight state or an airtight condition. In this case, what is necessary is just to form a pure water supply hole penetrated in a part corresponding to said pure water supply hole to each frame shape gasket in a thickness direction of the frame shape gasket concerned.
[0011] What is necessary is to attach a bolting board of a couple, where these are inserted, to bind the bolting board concerned tight, and just to bind tight therefore in detail, in order to hold said electrode conjugate, said diaphragm, and said collecting electrode plate to a laminating condition. Also in this case, what is necessary is just to form a pure water feed hopper penetrated in a part corresponding to said pure water supply hole to said one bolting board in a thickness direction of the bolting board concerned.
[0012] Next, in this invention said anode lateral electrode board, It is the electrode plate with which platinum was supported by sintered compact of zeolite, the Coral Sea sand, and particle powder of carbon black, and said cathode lateral electrode board is characterized by being the electrode plate with which a ruthenium was supported by sintered compact of zeolite and particle powder of carbon black. According to this invention person's experiment, by using this electrode plate, oxidative degradation of the hydrogen contained in pure water supplied to an anode lateral electrode board was carried out efficiently, and it was checked that power generation operation is efficiently performed under ordinary temperature. Therefore, it can generate electricity efficiently with an easy mechanism like before, without using fuel gas, such as methanol.
[0013] Next, this invention is characterized by an electric organ comprising the following.
A power generation module of the above-mentioned composition.
A pure water feed zone which supplies pure water to the power generation module concerned.
An air supply part which supplies air to said power generation module.

[0014] This invention is characterized by a power generation system comprising the following.
An electric organ of the above-mentioned composition.
A battery charger in which electric power generated with the electric organ concerned is stored.
An inverter for changing into alternating current a direct current generated with said electric organ, and outputting it.
As a battery charger, rechargeable batteries, such as an electric double layer capacitor, can be used.

[Effect of the Invention]
[0015] The power generation module of this invention can obtain the power generation capacity demanded easily, when only a required number laminates and carries out the series connection of the electrode conjugate of an identical configuration, and the group of a diaphragm. It can generate electricity efficiently under ordinary temperature by supplying pure water and air.
[Best Mode of Carrying Out the Invention]
[0016] The embodiment of the power generation system which applied this invention to below with reference to drawings is described.
[0017] (Entire configuration)
Drawing 1 is an outline lineblock diagram showing the power generation system which applied this invention. The power generation system 1 of this example is provided with the following.
Electric organ 2.
While storing the direct current generated with the electric organ 2 concerned, it changes into alternating current, and it is the controller 3 in which an output is possible.

[0018] The electric organ 2 is provided with the following.
Power generation module 4.
The pure water circulatory system 5 for supplying pure water to the power generation module 4 concerned.
The fan 6 for supplying air (oxygen) to the power generation module 4.
The internal electrical power source 8 for driving the pump of the cooling fan 7 for cooling the inside of an electric organ, the fan 6 and the cooling fan 7, and the pure water circulatory system 5.
Two or more rechargeable batteries 9 with which the controller 3 consists of electric double layer capacitors etc., It has the inverter 10 for changing a direct current into alternating current, the power generation current of the electric organ 2 is charged by the each second cell 9 via the relay 11, and current is supplied to the inverter 10 via the relay 12 from the rechargeable battery 9.
[0019] The pure water supply system 5 of the electric organ 2 is provided with the following.
Circulation tank 13.
The pure water circuit 14 for circulating the pure water currently stored in this circulation tank 13 via the power generation module 4.
The circulating pump 15 for circulating pure water along this pure water circuit 14.
It has the main tank 18 which can supply pure water from the inlet 17 arranged to the electric organ case 16. If the pure water in the circulation tank 13 becomes below the specified quantity, the feed pump 19 will drive and pure water will be supplied to the circulation tank 13 from the main tank 18. It has the recovery tank 20, the recovery tank 20 concerned is covered with the pure water collected from the power generation module 4 with air, and it is discharged from here from the drain exit 21 arranged to the electric organ case 16 if needed. It is possible to return the pure water collected by the recovery tank 20 to the circulation tank 13 side by the feed pump 22.
[0020] On the other hand, the direct current generated with the power generation module 4 is outputted to the internal electrical power source 8 and the controller 3 via the rectifier 23. The start switch 24 is arranged in the power supply passage to the controller 3, if the start switch 24 is made one, electric power will be supplied to each pumps 15, 19, and 22, the fan 6, and the cooling fan 7 via the relay 25 from the internal electrical power source 8, and these drives will begin. After the power generation state of the power generation module 4 is stable, supply of the power generation current by the side of the controller 3 is started. The controller 3 stores power generation current in the rechargeable battery 9, and changes a direct current into alternating current via the inverter 10, and starts supply of alternating current to the device (not shown) of a load side connected to the output terminal 26 of the controller 3 concerned.

[0021] (Power generation module)
Drawing 2 is a perspective view showing the power generation module 4, drawing 3 is an exploded perspective view of the power generation module 4, drawing 4 is an explanatory view showing the diaphragm, and drawing 5 is an explanatory view showing the flow of pure water.
[0022] The power generation module 4 is provided with the collecting electrode plate 41 of a couple, the diaphragm 44 of two or more sheets, and the electrode joint plate 42 of two or more sheets. The electrode joint plate 42 has the composition that lamination adhesion of the anode lateral electrode board 47 and the cathode lateral electrode board 48 was carried out on both sides of the electrolyte membrane 46. The electrode joint plate 42 of two or more sheets of this composition sandwiches the diaphragm 44, and the series connection is carried out. Each electrode joint plate (not shown) located in both ends sandwiches the diaphragm 44, respectively, and is connected to each collecting electrode plate 41. The gasket 43 of rectangular frame shape is pinched between the electrode joint plate 42 and the diaphragm 44 of both sides, respectively, and it changes between these into the fluid-tight state. Below, the composition of each portion is explained in detail.
[0023] First, the anode lateral electrode board 47 of the electrode conjugate 42 is an electrode plate with which platinum was supported by the sintered compact of zeolite, the Coral Sea sand, and the particle powder of carbon black. The cathode lateral electrode board 48 of another side is an electrode plate with which the ruthenium was supported by the sintered compact of zeolite and the particle powder of carbon black.
[0024] The locating holes 41a, 42a, 43a, and 44a which penetrate and extend in the corner section of the couple of those diagonal directions in those thickness directions are formed in the bolting board 41, the electric zygote 42, each gasket 43, each diaphragm 44, and each collecting electrode plate 45. These locating holes 41a-44a let an unillustrated gage pin pass, and these are laminated by the aligned state. Two or more boltholes 41b are formed in each bolting board, and these are unified by the laminating condition by the fastening bolt 49 which it let pass to these.
[0025] The pure water feed hoppers 41c, 42c, 43c, 44c, and 45c of the couple penetrated and prolonged in those thickness directions are formed in the corner section of the couple of another side of the diagonal direction of one bolting board 41, the electric zygote 42, each gasket 43, each diaphragm 44, and each collecting electrode plate 45. For example in the outer surface of one bolting board 41, pure water is supplied via the pure water supply pipe 50 connected to the upper pure water feed hopper 41c, and is discharged via the pure water supply pipe 50 connected to the lower pure water feed hopper 41c.
[0026] Let the collecting electrode plate 45 be the shape where 45 d of tag-block portions were prolonged up in constant width from one end of the upper bed side of a rectangular body plate portion. In this example, the collecting electrode plate 45 of two sheets is a thing of identical shape, and is arranged for reverse.
[0027] Next, the composition of the diaphragm 44 is explained with reference to drawing 4 and 5. One surface is made into the anode side surface 51, and, as for the diaphragm 44, the pure water supply groove 52 of the constant depth where both ends extend in parallel inside the periphery rectangular frame portion of constant width at the constant interval which is mutually open for free passage is minced here. The surface of another side of the diaphragm 44 is made into the cathode side surface 53, and, similarly the air supply slot 54 of the constant depth formed in the shape of a grid inside the periphery rectangular frame portion of constant width is formed here.
[0028] The air intake 59 of the same number is formed in the peripheral end faces 55 thru/or 58 of the neighborhood of the diaphragm 44, respectively, and each air intake 59 is open for free passage into the air supply slot 54 via the air duct 60 currently formed in the inside of a diaphragm. Therefore, the open air is supplied to the air supply slot 54 of each diaphragm 44 via the air intake 59. The air supplied to the air supply slot 54 of the cathode side surface 53 of the diaphragm 44 by the side of a cathode is supplied to the cathode lateral electrode board 48 of the electrode conjugate 42 which stands face to face against this.
[0029] The pure water supply hole 44c of the couple currently formed in the diaphragm 44 is open for free passage to the pure water supply groove 52 via the pure water passage 61 currently formed in the inside of a diaphragm. Therefore, the pure water supplied from the pure water supply pipe 50 of the bolting board 41 flows into the pure water supply hole 44c of the diaphragm 44 through the pure water supply holes 41c, 45c, and 43c, and is supplied to the pure water supply groove 52 through the pure water passage 62 inside a diaphragm from here. Since the electrode conjugate 42 is laminated in the state of fluid-tight via the gasket 43 by the anode side surface 51 of the diaphragm 44 in which the pure water supply groove 52 is formed, The pure water supply groove 52 is in the state where it was sealed, and it is supplied to the anode lateral electrode board 47 of the electrode conjugate 42, without pure water leaking and coming out outside.
[0030] The pure water supply hole 44c currently formed in the diaphragm 44, the gasket 43, the electrode conjugate 42, and the gasket 43 of another side here as shown in drawing 5, It passes along 43c, 42c, and 43c, pure water is supplied to the pure water supply hole 44c of the diaphragm 44 of the next step, and pure water is supplied to the pure water supply groove 52 of the diaphragm 44 concerned through the internal pure water passage 61 from here. The pure water which flowed through the pure water supply groove 52 of the diaphragm 44 concerned, and fell is discharged by the pure water supply hole 44c of another side through the internal pure water passage 61, from here, returns through the pure water supply holes 43c, 42c, 43c, and 44c, and is discharged outside.
[0031] Power generation capacity can be made to increase simply in the power generation module 4 of this composition by pinching the diaphragm 44 and the gasket 43 and increasing the number of sheets of the electrode conjugate 42 by which a series connection is carried out.
[0032] The power generation module 4 of this composition generates electricity according to the electrochemical reaction of pure water and a catalyst, and is fundamentally [ as the case of a general fuel cell ] the same. That is, if pure water is supplied to the anode electrode plate 47 (fuel electrode) as shown in drawing 6, it will be electrolyzed, hydrogen and oxygen will be generated and hydrogen will be divided into a hydrogen ion and a minus electron according to electrochemical reaction. Since hydrogen emits electrons, this reaction is oxidation reaction. The produced hydrogen ion moves to the cathode lateral electrode board 48 (oxygen pole) through the electrolyte membrane 46 (catalyst) of the electrode conjugate 42. Although the electrolyte membrane 46 has ionic permeability, since it does not let an electron pass, a minus electron is taken out outside via the collecting electrode plate 45 by the side of an anode. On the other hand, air is sent into the cathode lateral electrode board 48 (oxygen pole), the hydrogen ion to which the oxygen contained there is supplied through the electrolyte membrane 46 (catalyst), and the electron supplied from the outside via the collecting electrode plate 45 carry out a reduction reaction, and water is generated. Thereby, power generation is performed. The generated water is collected by the recovery tank 20 with air (refer to drawing 1).

[Brief Description of the Drawings]
[0033]
[Drawing 1]It is an outline lineblock diagram of the power generation system which applied this invention.
[Drawing 2]It is a perspective view showing the power generation module of the power generation system of drawing 1.
[Drawing 3]It is an exploded perspective view of the power generation module of drawing 2.
[Drawing 4]It is a perspective view showing the diaphragm of drawing 3.
[Drawing 5]It is an explanatory view showing the flow of pure water.
[Drawing 6]It is an explanatory view showing a power generation principle.

[Description of Notations]
[0034]
1 Power generation system
2 Electric organ
3 Controller
4 Power generation module
5 Pure water circulatory system
6 Fan
7 Cooling fan
8 Internal electrical power source
9 Rechargeable battery
10 Inverter
11, 12, and 25 Relay
13 Circulation tank
14 Circuit
15, 19, and 22 Pump
16 Case
17 Inlet
18 Main tank
20 Recovery tank
21 Outlet
24 Start switch
26 The output terminal of alternating current
41 Bolting board
42 Electrode conjugate
43 Gasket
44 Diaphragm
45 Collecting electrode plate
46 Electrolyte membrane
47 Anode lateral electrode board
48 Cathode lateral electrode board
49 Fastening bolt
50 Pure water supply pipe
41a - 45a locating hole
41c-45c Pure water supply hole
51 Anode side surface
52 Pure water supply groove
53 Cathode side surface
54 Air supply slot
55-58 Peripheral end face
59 Air incorporation mouth
60 Air duct
61 Pure water passage


--UNQUOTE

kavee

I am posting here the translation provided by Japanese patent office for the patent JP2005-281847A, which belongs to the same inventor, and titled same (Water Energy System)


QUOTE--

[Detailed Description of the Invention]
[Field of the Invention]
[0001]
This invention relates to the water electrolysis gas energy device which obtains combustion energy using hydrogen and oxygen which are produced by electrolyzing water.
[Background of the Invention]
[0002]
Conventionally, ** of the statement is known by JP,6-270140,A as this kind of art, for example. The electrolysis machine 101 which the device indicated in this gazette electrolyzes water as shown in drawing 4, and generates oxyhydrogen gas, The defoaming machine 103 of oxyhydrogen gas connected to this electrolysis machine 101 via the condensator 102, The tank 108 connected with said defoaming machine 103 in parallel with the enrichment machine 107 of oxyhydrogen gas connected to this defoaming machine 103, and this enrichment machine 107, The burner 110 connected with each of said enrichment machine 107 and said tank 108, It consists of the dry seals 112 and 112a with a check valve respectively provided between said enrichment machine 107, this burner 110, and said tank 108 and this burner 110, and the control block 113 which controls or supervises the electrolytic current of said electrolysis machine 101, a pressure, and temperature.
[0003]
Since this conventional water electrolysis gas plant formed the defoaming machine 103 between said electrolysis machine 101, the enrichment machine 107, and the tank 108, Since the bubble of the electrolysis solution accompanied to oxyhydrogen gas was removed efficiently and the safety valve 104 was formed in said defoaming machine 103, it enables it to hold the operation stability of the electrolysis machine 101 at the time of the pressure buildup of the foam-containing oxyhydrogen gas emitted. Since the gas valves 111 and 111a which branched in parallel with the tank 108 and the enrichment machine 107 from said defoaming machine 103, and became independent to the burner 110 at Mr. connection and the branching interconnecting tubes 118 and 118a were attached, The mixed amount of the oxyhydrogen gas of enrichment machine 107 and tank 108 empty is adjusted free, and it enables it to acquire the gas flame of the temperature of the request according to the flame processing of various materials.
[0004]
In said enrichment machine 107, since the jet hole of an inner lift and the outlet of the outer tub were provided exactly the other way around, mixed enrichment gas dries remarkably and, for this reason, the attachment of a gas oven can be excluded.
[0005]
And while unifying the dry seals 112 and 112a and said check valve of said burner 110 and simplifying the composition of a device, Since this dry seal with a check valve was provided between said burner 110, said enrichment machine 107, and said tank 108, a flame can be intercepted and a blast can be eliminated. And making a water layer placed between said enrichment machine 107 and said tank 108 and an interval can keep safety remarkable to the prevention from a backfire.
[Problem(s) to be Solved by the Invention]
[0006]
However, the above-mentioned conventional water electrolysis gas plant was what must take the high gas pressure of the oxyhydrogen gas to generate, in order for the gas has an enrichment machine, a tank, and a double tub and emitted [ these double tubs ] besides a defoaming machine to pass smoothly. Therefore, the device was enlarged, and simple usage could not be done as a result, but there was a fault that it could not be used only at welding, others, and a comparatively large-sized place.
[0007]
This invention will provide the water electrolysis gas energy device which raised the use which can use a device as a small and simple thing in view of the fault on the above-mentioned conventional technology. That is, this invention will use [ which obtains fuel gas (mixture of hydrogen and oxygen) and replaces this with propane by electrolysis of an alkaline aqueous solution ] it as gas energy.
[Means for Solving the Problem]
[0008]
In a water electrolysis gas energy device of a statement, this application claim book 1 comprises:
An electrolytic device which poured in a caustic-alkali-of-sodium solution of prescribed concentration as electrolytic water.
Two or more electrodes which are arranged in a predetermined gap at the electrolytic device, and have a gas port for gas passing in the upper part.
A spacer which is arranged inter-electrode [ these / two or more ], and forms a predetermined electrolysis field in each inter-electrode one.
An electric control circuit which impresses predetermined voltage current to said two or more electrodes.
A condensator which cools production gas drawn from the gas port 2 of two or more of said electrodes.
A defoaming machine which has arranged a ceramic catalyst which removes the shape of a bubble intermingled in production gas cooled inside.
A solution mixer which mixes gas from this defoaming machine to water and a predetermined bulking agent.

[Best Mode of Carrying Out the Invention]
[0009]
As an alkaline aqueous solution, a caustic-alkali-of-sodium solution is used for this invention as electrolytic water 10%, it electrolyzes this using 100V commercial power, and the oxygen water matter mixed gas emitted with a predetermined defoaming machine. By taking out only gas constituents and passing further the bulking agent which consists this of water and gasoline, it is generated under low pressure and the gas energy which replaces with fuel, such as usual propane, and can be equal to use is acquired.
[Example]
[0010]
One example of the water electrolysis gas energy device concerning this invention is described in detail based on a drawing. Drawing 1 is the whole example device perspective view showing the example of the water electrolysis gas energy device.
[0011]
In drawing 1, an electrolytic device and 2 1 a condensator and 3, It is a solution mixer with which the solution inlet where a safety valve and 4 pour a defoaming machine into the defoaming machine 4, and 5 pours a solution into it, and 6 mix an electrical connection gauge, and 7 mixes water and a bulking agent, and has the content volume of 3.78 l. as the content volume. The drain mouth of solution and 12 are electrolysis solution water-refilling mouths the ceramic catalyst which the inlet where 8 pours in the water or a bulking agent, and 9 have been arranged at the gas valve, and has been arranged in said defoaming machine 4 10, and 11.
[0012]
In this example, using a 10% caustic-alkali-of-sodium solution as an electrolysis solution poured into said electrolytic device 1, the same 10% caustic-alkali-of-sodium solution is poured in also into said defoaming machine 4, and this is used as a defoaming solution. And if the electrolysis solution poured in from said electrolysis solution water-refilling mouth 12 is filled to predetermined water level in the electrolytic device 1, from the liquid port 14 established in this electrolytic device 1, it will pass along the pipe 15 and this electrolysis solution will be filled also in said defoaming machine 4. The electrolysis solution led in this defoaming machine 4 is filled to predetermined water level within the defoaming machine 4, and the oxygen water matter gas emitted from said electrolytic device 1 in this state is drawn.
[0013]
He is trying to pour into said solution mixer 7 the mixer liquid which comprised a ratio of the gasoline 0.2l (liter) as a bulking agent to the water 0.75l (liter). And the oxygen water matter mixed gas drawn from the gas exhaust 13 of said electrolytic device 1, After being cooled, pass along said condensator 2, and it is led to said defoaming machine 4, and in this defoaming machine 4. Further, defoaming is carried out via the ceramic catalyst 10 provided in the inside, this oxygen water matter mixed gas by which defoaming was carried out is led to said solution mixer 7 after that, it sends to gas range 16 grade, it is burned [ the gas mass flow from this mixer 7 is adjusted with said gas valve 9, ], and it uses as gas energy.
[0014]
In this example, first, in order to obtain oxygen water matter mixed gas, specified quantity pouring of the caustic-alkali-of-sodium solution is carried out 10%, the direct current voltage of 5-20A is obtained to said electrolytic device 1, this is impressed to the electrode of this electrolytic device 1, and oxygen water matter mixed gas is obtained from 100V commercial power to it at this.
[0015]
The outline of said electrolytic device 1 is shown in drawing 2. Drawing 2 (a) shows the outline of this electrolytic device 1, it is shown that electrode 20 1 made from stainless steel, 20 2, 20 3, and ... are arranged by the predetermined interval, and the figure (b) shows the top view and elevational view of an electrode showing the shape structure of the one-sheet electrode 20 of one sheet. the figure (c) -- each electrode 20 1, 20 2, 20 3, and --- it is a sectional view showing forming electrolysis field 25 1, 25 2, 25 3, and ... with the packing 21 arranged in between.
[0016]
Namely, as for the electrode plate 20, as shown in the drawing 2 (b), one side has the shape of a square (195 mm x 195 mm), a stainless plate about 1 mm thick -- on the way -- alike -- each electrode 20 1, 20 2, 20 3, and ... since the packing 21 arranged with a predetermined gap in between does not shift, it has a gap of gently-sloping concave shape in the center for the intensity of electrode plate 20 the very thing. And loading slot 22 1 in which the joint bolt (outside of a graphic display) made to energize in order that it may impress the voltage of an anode or a negative electrode, while each electrode plate 20 makes a prescribed position arrange each electrode plate is inserted, The opening of 22 2, 22 3, and the 22 4 is carried out to the four corners of each of said electrode plate 20.
[0017]
For this reason, each electrode 20 1, 20 2, 20 3, field 25 1 that is ..., and was divided and constituted, 25 2, 25 3, and ---, When an electrolysis solution is filled, this field 25 1, 25 2, A cell is formed in 25 3 and ..., and if voltage predetermined to electrode 20 1 arranged at both sides, 20 2, 20 3, and --- makes it impress, gaseous oxygen or gaseous hydrogen will occur in the field concerned.
[0018]
When each electrode 20 has been arranged in the prescribed position and predetermined voltage is impressed to each electrode plate 20 inter-electrode, The opening of the gas port 23 which condenses and leads each 25 1 in a field, 25 2, 25 3, and the oxygen water matter mixed gas emitted from the electrolysis solution of ... to a determined direction is carried out to the upper position of the center of each electrode plate 20. this gas port 23 -- each electrode 20 1, 20 2, 20 3, and ... oxygen gas emitted in between and hydrogen gas condense, and it is led to said defoaming machine 4 from the gas exhaust 13 of said electrolytic device 1 as oxygen water matter mixed gas in end.
[0019]
Next, the electric control of the water electrolysis gas energy device used for this example is explained. Drawing 3 is a schematic diagram of the electric control circuit of the water electrolysis gas energy device concerning this example.
[0020]
In drawing 3, 30 is a power supply and commercial 100V power supply is used in this example. 31 is a thyristor which rectifies this commercial power, and that output is supplied to the electrode 20 in said electrolytic device 1.
[0021]
In said electrolytic device 1 and said defoaming machine 4, and the mixer 7. Each the output from each sensor apparatus 32 which the sensor apparatus 32 which induces an internal pressure and temperature was formed, and was formed in said these electrolytic devices 1, said defoaming machine 4, and the mixer 7, While being sent to the pressure monitor means 33 and the temperature monitoring means 34 and displaying the pressure and temperature in each of these devices by the indicator 35 in these pressure monitor means 33 and temperature monitoring means 34, it is monitored continuously whether those pressures and temperature exceed a predetermined value. And if the pressure and temperature of each device exceed a predetermined preset value, they will send this to the alarm equipment 36, and they will emit a predetermined alarm.
[0022]
Namely, if it has an automatic input switch (outside of a graphic display) which protects the electric apparatus concerned from excess voltage and a short circuit (short) to said power supply 30 and switch one of the power supply 30 is carried out, while a starter will drive, While electric power is supplied for the fan (outside of a graphic display) formed in each part to the surroundings and a control power bridge (outside of a graphic display), the electric power indicator (outside of a graphic display) of the indicator 35 lights up.
[0023]
The control unit (outside of a graphic display) which controls the deployed angle of said thyristor 31 to said power supply 30, It has a control unit (outside of a graphic display) which controls the temperature of said electrolytic device 1, and the pressure of oxygen water matter mixed gas generated, It is constituted so that the voltage concerning the deployed angle of said thyristor 31, i.e., each electrode 20 1 of said electrolytic device 1, 20 2, 20 3, and ... may be controlled.
[0024]
And if the voltage in sync with the voltage concerning said control power bridge is impressed, Electrode 20 1, 20 3 which were connected to said thyristor 31, It charges until it reaches the operating potential of the transistor which generates ... and the positive pulse which takes 20 6 for ... 20 4 20 2 20 5, The positive charge which hits at the half year of said synchronous voltage will be impressed to an anode, and one of said thyristors 31 will be in an ON state, Voltage is impressed to electrode 20 1, 20 2, 20 3, and ..., each electrode 20 1, 20 3, and 20 5 ... and 20 2, 20 4, and 20 6 ... field 25 1 constituted in between, 25 2, 25 3, and ... oxygen gas or hydrogen gas is generated inside, respectively.
[0025]
Opposite polar voltage in the next half year of synchronous voltage And each electrode 20 1, 20 5 20 3 ... and 20 2, 20 4, It is impressed by ... 20 6 and similarly Each electrode 20 1, 20 3 and 20 5 ... and field 25 1 which comprises ... 20 6 20 4 20 2, 25 2, 25 3, and ... hydrogen gas and oxygen gas are generated inside, respectively.
[0026]
In said electrolytic device 1, to a continuous monitoring state, temperature and a pressure supply electric power at said thyristor 31, when the temperature and the pressure in he and the electrolytic device 1 are below a preset value, and they suspend in it supply of the voltage on which they will be impressed to said thyristor 31 if said temperature and a pressure become beyond a preset value. thus, the oxygen gas and hydrogen gas which are generated one by one -- each field 25 1, 25 2, 25 3, and ... it is accumulated above [ inner ], it passes along the gas port 23 provided above said electrode 20, and is led to said defoaming machine 4.
[0027]
Thus, in this example, the oxygen gas and hydrogen gas which state the oxygen water matter mixed gas generated to the basis of the following generation conditions below are generated.
1) In the maximum current 5A at the time of commercial power 100V250Hz - the power consumption of 20A above, the generation ratio of the oxygen water matter mixed gas emitted becomes the following.
3) Less than 0.15 l/Hr of less than 0.6 l/Hr of amounts-of-consumption (amount of electrolysis) 5 hydrocarbon content fluid (gasoline) amounts of consumption of 0.2-1.12/of mixture production quantity Hr4 water of hydrogen and oxygen
[0028]
The sizes of the electrolytic device 1 in this example and the mixer 7 are as follows.
6) In the electrolytic device cistern of the capacity of the electrolytic device cistern capacity 10.0l. above, 8.1l. of solution of 10% of caustic alkali of sodium was poured out, and the cistern was filled.
7) The mixer 7 of the capacity of the solution mixer capacity 3.78l. above was filled with the mixer liquid 0.95l which consists of the water 0.75l+ gasoline 0.2l, and the cistern of the mixer 7 was filled. On the above-mentioned conditions, when continuous operation is performed for 8 hours, 4.8l. of electrolysis solutions are consumed and the yield based on the formula 1 in the oxygen water matter mixed gas generated in the meantime is obtained.
[0029]
ID=000003


[Effect of the Invention]
[0030]
According to this invention, a certain commercial power can be used close, oxygen water matter mixed gas can be obtained very simple, and it is [ when ] effective in the ability to use it anywhere as fuel gas replaced with propane. And since this fuel gas is obtained by electrolysis decomposition, it can obtain an alkaline aqueous solution to pollution-free and low cost.
[0031]
Since the enrichment machine which this kind of device needed is not needed conventionally according to the water electrolysis gas energy device concerning the invention in this application and it can be considered as that part and a small and lightweight device, if there is even electric power, even if it faces movement, it can be considered as a very useful gas energy device.
[0032]
Since the miniaturization of the part and concave S value can be attained since it compares with a device conventionally and enabled it to work with low pressure, and it can work with low pressure, it can be considered as the device which is equal to continuation generating, and has the extremely outstanding effect that a maintenance and others can be performed minor.
[Example]
One example of the water electrolysis gas energy device concerning this invention is described in detail based on a drawing. Drawing 1 is the whole example device perspective view showing the example of the water electrolysis gas energy device.
[0011]
In drawing 1, an electrolytic device and 2 1 a condensator and 3, It is a solution mixer with which the solution inlet where a safety valve and 4 pour a defoaming machine into the defoaming machine 4, and 5 pours a solution into it, and 6 mix an electrical connection gauge, and 7 mixes water and a bulking agent, and has the content volume of 3.78 l. as the content volume. The drain mouth of solution and 12 are electrolysis solution water-refilling mouths the ceramic catalyst which the inlet where 8 pours in the water or a bulking agent, and 9 have been arranged at the gas valve, and has been arranged in said defoaming machine 4 10, and 11.
[0012]
In this example, using a 10% caustic-alkali-of-sodium solution as an electrolysis solution poured into said electrolytic device 1, the same 10% caustic-alkali-of-sodium solution is poured in also into said defoaming machine 4, and this is used as a defoaming solution. And if the electrolysis solution poured in from said electrolysis solution water-refilling mouth 12 is filled to predetermined water level in the electrolytic device 1, from the liquid port 14 established in this electrolytic device 1, it will pass along the pipe 15 and this electrolysis solution will be filled also in said defoaming machine 4. The electrolysis solution led in this defoaming machine 4 is filled to predetermined water level within the defoaming machine 4, and the oxygen water matter gas emitted from said electrolytic device 1 in this state is drawn.
[0013]
He is trying to pour into said solution mixer 7 the mixer liquid which comprised a ratio of the gasoline 0.2l (liter) as a bulking agent to the water 0.75l (liter). And the oxygen water matter mixed gas drawn from the gas exhaust 13 of said electrolytic device 1, After being cooled, pass along said condensator 2, and it is led to said defoaming machine 4, and in this defoaming machine 4. Further, defoaming is carried out via the ceramic catalyst 10 provided in the inside, this oxygen water matter mixed gas by which defoaming was carried out is led to said solution mixer 7 after that, it sends to gas range 16 grade, it is burned [ the gas mass flow from this mixer 7 is adjusted with said gas valve 9, ], and it uses as gas energy.
[0014]
In this example, first, in order to obtain oxygen water matter mixed gas, specified quantity pouring of the caustic-alkali-of-sodium solution is carried out 10%, the direct current voltage of 5-20A is obtained to said electrolytic device 1, this is impressed to the electrode of this electrolytic device 1, and oxygen water matter mixed gas is obtained from 100V commercial power to it at this.
[0015]
The outline of said electrolytic device 1 is shown in drawing 2. Drawing 2 (a) shows the outline of this electrolytic device 1, it is shown that electrode 20 1 made from stainless steel, 20 2, 20 3, and ... are arranged by the predetermined interval, and the figure (b) shows the top view and elevational view of an electrode showing the shape structure of the one-sheet electrode 20 of one sheet. the figure (c) -- each electrode 20 1, 20 2, 20 3, and --- it is a sectional view showing forming electrolysis field 25 1, 25 2, 25 3, and ... with the packing 21 arranged in between.
[0016]
Namely, as for the electrode plate 20, as shown in the drawing 2 (b), one side has the shape of a square (195 mm x 195 mm), a stainless plate about 1 mm thick -- on the way -- alike -- each electrode 20 1, 20 2, 20 3, and ... since the packing 21 arranged with a predetermined gap in between does not shift, it has a gap of gently-sloping concave shape in the center for the intensity of electrode plate 20 the very thing. And loading slot 22 1 in which the joint bolt (outside of a graphic display) made to energize in order that it may impress the voltage of an anode or a negative electrode, while each electrode plate 20 makes a prescribed position arrange each electrode plate is inserted, The opening of 22 2, 22 3, and the 22 4 is carried out to the four corners of each of said electrode plate 20.
[0017]
For this reason, each electrode 20 1, 20 2, 20 3, field 25 1 that is ..., and was divided and constituted, 25 2, 25 3, and ---, When an electrolysis solution is filled, this field 25 1, 25 2, A cell is formed in 25 3 and ..., and if voltage predetermined to electrode 20 1 arranged at both sides, 20 2, 20 3, and --- makes it impress, gaseous oxygen or gaseous hydrogen will occur in the field concerned.
[0018]
When each electrode 20 has been arranged in the prescribed position and predetermined voltage is impressed to each electrode plate 20 inter-electrode, The opening of the gas port 23 which condenses and leads each 25 1 in a field, 25 2, 25 3, and the oxygen water matter mixed gas emitted from the electrolysis solution of ... to a determined direction is carried out to the upper position of the center of each electrode plate 20. this gas port 23 -- each electrode 20 1, 20 2, 20 3, and ... oxygen gas emitted in between and hydrogen gas condense, and it is led to said defoaming machine 4 from the gas exhaust 13 of said electrolytic device 1 as oxygen water matter mixed gas in end.
[0019]
Next, the electric control of the water electrolysis gas energy device used for this example is explained. Drawing 3 is a schematic diagram of the electric control circuit of the water electrolysis gas energy device concerning this example.
[0020]
In drawing 3, 30 is a power supply and commercial 100V power supply is used in this example. 31 is a thyristor which rectifies this commercial power, and that output is supplied to the electrode 20 in said electrolytic device 1.
[0021]
In said electrolytic device 1 and said defoaming machine 4, and the mixer 7. Each the output from each sensor apparatus 32 which the sensor apparatus 32 which induces an internal pressure and temperature was formed, and was formed in said these electrolytic devices 1, said defoaming machine 4, and the mixer 7, While being sent to the pressure monitor means 33 and the temperature monitoring means 34 and displaying the pressure and temperature in each of these devices by the indicator 35 in these pressure monitor means 33 and temperature monitoring means 34, it is monitored continuously whether those pressures and temperature exceed a predetermined value. And if the pressure and temperature of each device exceed a predetermined preset value, they will send this to the alarm equipment 36, and they will emit a predetermined alarm.
[0022]
Namely, if it has an automatic input switch (outside of a graphic display) which protects the electric apparatus concerned from excess voltage and a short circuit (short) to said power supply 30 and switch one of the power supply 30 is carried out, while a starter will drive, While electric power is supplied for the fan (outside of a graphic display) formed in each part to the surroundings and a control power bridge (outside of a graphic display), the electric power indicator (outside of a graphic display) of the indicator 35 lights up.
[0023]
The control unit (outside of a graphic display) which controls the deployed angle of said thyristor 31 to said power supply 30, It has a control unit (outside of a graphic display) which controls the temperature of said electrolytic device 1, and the pressure of oxygen water matter mixed gas generated, It is constituted so that the voltage concerning the deployed angle of said thyristor 31, i.e., each electrode 20 1 of said electrolytic device 1, 20 2, 20 3, and ... may be controlled.
[0024]
And if the voltage in sync with the voltage concerning said control power bridge is impressed, Electrode 20 1, 20 3 which were connected to said thyristor 31, It charges until it reaches the operating potential of the transistor which generates ... and the positive pulse which takes 20 6 for ... 20 4 20 2 20 5, The positive charge which hits at the half year of said synchronous voltage will be impressed to an anode, and one of said thyristors 31 will be in an ON state, Voltage is impressed to electrode 20 1, 20 2, 20 3, and ..., each electrode 20 1, 20 3, and 20 5 ... and 20 2, 20 4, and 20 6 ... field 25 1 constituted in between, 25 2, 25 3, and ... oxygen gas or hydrogen gas is generated inside, respectively.
[0025]
Opposite polar voltage in the next half year of synchronous voltage And each electrode 20 1, 20 5 20 3 ... and 20 2, 20 4, It is impressed by ... 20 6 and similarly Each electrode 20 1, 20 3 and 20 5 ... and field 25 1 which comprises ... 20 6 20 4 20 2, 25 2, 25 3, and ... hydrogen gas and oxygen gas are generated inside, respectively.
[0026]
In said electrolytic device 1, to a continuous monitoring state, temperature and a pressure supply electric power at said thyristor 31, when the temperature and the pressure in he and the electrolytic device 1 are below a preset value, and they suspend in it supply of the voltage on which they will be impressed to said thyristor 31 if said temperature and a pressure become beyond a preset value. thus, the oxygen gas and hydrogen gas which are generated one by one -- each field 25 1, 25 2, 25 3, and ... it is accumulated above [ inner ], it passes along the gas port 23 provided above said electrode 20, and is led to said defoaming machine 4.
[0027]
Thus, in this example, the oxygen gas and hydrogen gas which state the oxygen water matter mixed gas generated to the basis of the following generation conditions below are generated.
1) In the maximum current 5A at the time of commercial power 100V250Hz - the power consumption of 20A above, the generation ratio of the oxygen water matter mixed gas emitted becomes the following.
3) Less than 0.15 l/Hr of less than 0.6 l/Hr of amounts-of-consumption (amount of electrolysis) 5 hydrocarbon content fluid (gasoline) amounts of consumption of 0.2-1.12/of mixture production quantity Hr4 water of hydrogen and oxygen
[0028]
The sizes of the electrolytic device 1 in this example and the mixer 7 are as follows.
6) In the electrolytic device cistern of the capacity of the electrolytic device cistern capacity 10.0l. above, 8.1l. of solution of 10% of caustic alkali of sodium was poured out, and the cistern was filled.
7) The mixer 7 of the capacity of the solution mixer capacity 3.78l. above was filled with the mixer liquid 0.95l which consists of the water 0.75l+ gasoline 0.2l, and the cistern of the mixer 7 was filled. On the above-mentioned conditions, when continuous operation is performed for 8 hours, 4.8l. of electrolysis solutions are consumed and the yield based on the formula 1 in the oxygen water matter mixed gas generated in the meantime is obtained.
[0029]
ID=000004


ID=000005


[Field of the Invention]
This invention relates to the water electrolysis gas energy device which obtains combustion energy using hydrogen and oxygen which are produced by electrolyzing water.
[Background of the Invention]
Conventionally, ** of the statement is known by JP,6-270140,A as this kind of art, for example. The electrolysis machine 101 which the device indicated in this gazette electrolyzes water as shown in drawing 4, and generates oxyhydrogen gas, The defoaming machine 103 of oxyhydrogen gas connected to this electrolysis machine 101 via the condensator 102, The tank 108 connected with said defoaming machine 103 in parallel with the enrichment machine 107 of oxyhydrogen gas connected to this defoaming machine 103, and this enrichment machine 107, The burner 110 connected with each of said enrichment machine 107 and said tank 108, It consists of the dry seals 112 and 112a with a check valve respectively provided between said enrichment machine 107, this burner 110, and said tank 108 and this burner 110, and the control block 113 which controls or supervises the electrolytic current of said electrolysis machine 101, a pressure, and temperature.
[0003]
Since this conventional water electrolysis gas plant formed the defoaming machine 103 between said electrolysis machine 101, the enrichment machine 107, and the tank 108, Since the bubble of the electrolysis solution accompanied to oxyhydrogen gas was removed efficiently and the safety valve 104 was formed in said defoaming machine 103, it enables it to hold the operation stability of the electrolysis machine 101 at the time of the pressure buildup of the foam-containing oxyhydrogen gas emitted. Since the gas valves 111 and 111a which branched in parallel with the tank 108 and the enrichment machine 107 from said defoaming machine 103, and became independent to the burner 110 at Mr. connection and the branching interconnecting tubes 118 and 118a were attached, The mixed amount of the oxyhydrogen gas of enrichment machine 107 and tank 108 empty is adjusted free, and it enables it to acquire the gas flame of the temperature of the request according to the flame processing of various materials.
[0004]
In said enrichment machine 107, since the jet hole of an inner lift and the outlet of the outer tub were provided exactly the other way around, mixed enrichment gas dries remarkably and, for this reason, the attachment of a gas oven can be excluded.
[0005]
And while unifying the dry seals 112 and 112a and said check valve of said burner 110 and simplifying the composition of a device, Since this dry seal with a check valve was provided between said burner 110, said enrichment machine 107, and said tank 108, a flame can be intercepted and a blast can be eliminated. And making a water layer placed between said enrichment machine 107 and said tank 108 and an interval can keep safety remarkable to the prevention from a backfire.
[Effect of the Invention]
According to this invention, a certain commercial power can be used close, oxygen water matter mixed gas can be obtained very simple, and it is [ when ] effective in the ability to use it anywhere as fuel gas replaced with propane. And since this fuel gas is obtained by electrolysis decomposition, it can obtain an alkaline aqueous solution to pollution-free and low cost.
[0031]
Since the enrichment machine which this kind of device needed is not needed conventionally according to the water electrolysis gas energy device concerning the invention in this application and it can be considered as that part and a small and lightweight device, if there is even electric power, even if it faces movement, it can be considered as a very useful gas energy device.
[0032]
Since the miniaturization of the part and concave S value can be attained since it compares with a device conventionally and enabled it to work with low pressure, and it can work with low pressure, it can be considered as the device which is equal to continuation generating, and has the extremely outstanding effect that a maintenance and others can be performed minor.
[Problem(s) to be Solved by the Invention]
However, the above-mentioned conventional water electrolysis gas plant was what must take the high gas pressure of the oxyhydrogen gas to generate, in order for the gas has an enrichment machine, a tank, and a double tub and emitted [ these double tubs ] besides a defoaming machine to pass smoothly. Therefore, the device was enlarged, and simple usage could not be done as a result, but there was a fault that it could not be used only at welding, others, and a comparatively large-sized place.
[0007]
This invention will provide the water electrolysis gas energy device which raised the use which can use a device as a small and simple thing in view of the fault on the above-mentioned conventional technology. That is, this invention will use [ which obtains fuel gas (mixture of hydrogen and oxygen) and replaces this with propane by electrolysis of an alkaline aqueous solution ] it as gas energy.
[Means for Solving the Problem]
In a water electrolysis gas energy device of a statement, this application claim book 1 comprises:
An electrolytic device which poured in a caustic-alkali-of-sodium solution of prescribed concentration as electrolytic water.
Two or more electrodes which are arranged in a predetermined gap at the electrolytic device, and have a gas port for gas passing in the upper part.
A spacer which is arranged inter-electrode [ these / two or more ], and forms a predetermined electrolysis field in each inter-electrode one.
An electric control circuit which impresses predetermined voltage current to said two or more electrodes.
A condensator which cools production gas drawn from the gas port 2 of two or more of said electrodes.
A defoaming machine which has arranged a ceramic catalyst which removes the shape of a bubble intermingled in production gas cooled inside.
A solution mixer which mixes gas from this defoaming machine to water and a predetermined bulking agent.

[Best Mode of Carrying Out the Invention]
[0009]
As an alkaline aqueous solution, a caustic-alkali-of-sodium solution is used for this invention as electrolytic water 10%, it electrolyzes this using 100V commercial power, and the oxygen water matter mixed gas emitted with a predetermined defoaming machine. By taking out only gas constituents and passing further the bulking agent which consists this of water and gasoline, it is generated under low pressure and the gas energy which replaces with fuel, such as usual propane, and can be equal to use is acquired.
[Brief Description of the Drawings]
[Drawing 1]Drawing 1 is the whole example device perspective view showing the example of a water electrolysis gas energy device,
[Drawing 2]As for the figure showing the outline of this electrolytic device 1, and drawing 2 (b), in drawing 2 (a), the top view and the elevational view, and drawing 2 (c) in which the shape structure of each electrode is shown are the electrolysis field **** sectional views formed by the electrode of said plurality, and the packing arranged in the meantime,
[Drawing 3]The schematic diagram of the electric control circuit of the water electrolysis gas energy device concerning drawing 3 this example,
[Drawing 4]Drawing 4 is a figure showing the outline of the conventional water electrolysis gas plant.
[Description of Notations]
1 ... Electrolytic device,
2 ... Condensator,
3 ... Safety valve,
4 ... Defoaming machine,
5 ... Chemical-feeding mouth,
6 ... Electrical connection gauge
7 ... Solution mixer,
8 ... Inlet
9 ... Gas valve
10 ... Ceramic catalyst,
11 ... Drain cock
12 ... Electrolysis solution water-refilling mouth
13 ... Gas exhaust
14 ... Liquid port,
15 ... Pipe
16 ... Gas range
20 ... Electrode plate,
21 ... Packing,
22 ... Loading slot,
23 ... Gas port
25 ... Electrolysis field,
30 ... Power supply,
32 ... Sensor apparatus
33 ... Pressure monitor means,
34 ... Temperature monitoring means,
35 ... Indicator,
36 ... Alarm equipment,
101 ... Electrolysis machine,
102 ... Condensator,
103 ... Defoaming machine,
104 ... Safety valve,
107 ... Enrichment machine,
108 ... Tank,
110 ... Burner,
111 ... Gas valve
112 ... Dry seal,
112 ... Dry seal with a check valve,
113 ... Control block
118 ... Branching interconnecting tube,

--UNQUOTE