KR20090012535A - A portable apparatus for generating hydrogen without limiting direction - Google Patents

Abstract

A portable non-directional hydrogen generator is provided to realize the stable supply of hydrogen and to conveniently charge the fuel solution by separating a fuel tank. In an apparatus generating the hydrogen by contacting the fuel solution with a catalyst coated on a supporter to supply the hydrogen selectively to the product using the hydrogen as the fuel, a portable non-directional hydrogen generator comprises an action tube(100) mounted at one side of the fuel battery(F); a supporter(110) which is guided in the inner side of the reaction supporter with the mobile tool installed at one end of the reaction tube; a fuel tank(200) which is accommodated in a state where the other end part of the reaction tube is dipped in the fuel solution and is combined and separated with/from a container tub(210) and container cover(220) by a clamping device; and a hydrogen collecting device part which is installed by connecting a fuel battery and the inside of a fuel tank and supplies the hydrogen generated in the fuel tank to the fuel battery.

Description

A portable apparatus for generating hydrogen without limiting direction}

The present invention relates to a hydrogen generator, and more particularly, portable non-directional hydrogen generation to realize a stable supply of hydrogen without limiting the direction of the product, the fuel tank can be separated to simplify the filling of the fuel solution Relates to a device.

Today, while the standard of living is improving with the development of industrial technology, the proliferation of energy is causing serious problems of environmental pollution and resource depletion. In order to solve the problems of environmental pollution and resource depletion, the situation is focused on the development of clean fuel. Among the clean fuels described above, the development of clean alternative energy using hydrogen as an energy source has attracted great attention.

The reason is that hydrogen is one of the most abundant resources on earth, and generates large energy by reacting with oxygen while generating only water as a by-product, thereby solving the problem of resource depletion as well as environmental pollution.

As one of the methods for using hydrogen as a fuel, hydrogen is stored in a high pressure tank in a gaseous state, and then hydrogen is discharged at a desired pressure through a pressure reducing valve, thereby supplying hydrogen to a product requiring hydrogen. .

However, the hydrogen supply method requires a separate hydrogen storage pressure vessel capable of withstanding 120 atm to 200 atm, and because the pressure vessel is large and heavy, it is inconvenient to move and it is difficult to maintain the confidentiality of hydrogen. There is concern.

In particular, portable electronic devices such as mobile phones and laptops were inherently impossible to carry pressure vessels capable of storing high pressure hydrogen. However, even if the above-mentioned pressure vessel can be loaded on a vehicle, it is difficult to limit the amount of fuel and minimize the volume and weight of the fuel tank because several pressure vessels for storing high-pressure and high-pressure hydrogen have to be loaded.

In order to solve this problem, a method of generating hydrogen by a reaction between a fuel solution and a catalyst has been proposed. Such a method is a principle of generating hydrogen gas by contacting an aqueous hydride solution with a catalyst, and a configuration in which the catalytic reaction should be stopped when hydrogen is not used, such as during standby operation or when power is cut off without using hydrogen. It must be equipped.

In addition, the portable non-directional compact structure, the structure that can prevent high pressure formation in the fuel solution tank, the structure that can store the oxide in the form of powder as a reaction product, and even for long-term use A reliable configuration must be in place to ensure that no problems arise.

1 to 2B illustrate a conventional self-active hydrogen generator (Korean Patent Publication No. 2004-0084647), which is one example of the hydrogen generator as described above. A hydrogen outlet 12 is provided in the fuel tank 10, the fuel solution 17 of the hydrogen storage material is stored in a state dissolved in the fuel tank 10, and the fuel solution 17 of the hydrogen storage material is stored. The catalyst 21 is provided in the catalytic reaction tube 20 so as to be in contact with the hydrogen to generate hydrogen.

Here, the catalytic reaction tube 20 is a closure 27 for blocking the contact of the fuel solution 17 and the catalyst 21 when the pressure in the fuel tank 10 is increased, and the use of hydrogen in the fuel cell When the pressure in the fuel tank 10 is reduced according to the opening portion 28 to make contact with the fuel solution 17 and the catalyst 21 is made, the elasticity having a compressive and restoring force to control the hydrogen generation Means 24.

That is, the fuel solution 17 is stored in the sealed fuel tank 10 and the catalyst reaction tube 20 is provided therein, so that when the hydrogen is required, the catalyst of the fuel solution 17 and the catalyst reaction tube 20 is required. (21) comes into contact with each other to generate hydrogen. On the other hand, when hydrogen is not used, the outlet 12 is closed and the hydrogen pressure in the hermetic fuel tank 10 is increased by a certain amount or more, so that the catalyst 21 overcomes the elasticity of the elastic means 24 by the force. Then, it pushes in, and the contact with the fuel solution 17 is interrupted, and hydrogen generation stops.

Meanwhile, FIGS. 3A and 3B illustrate a hydrogen generator (Korean Patent Registration No. 10-524867), which is another example of the above-described hydrogen generator, and includes a housing 11, a bellows 24, a reaction rod 20, and a pressurization. Means.

In other words, first, the housing 11 accommodates the metal hydride solution 19 and has a first space 12 therein, which is a place where a hydrogen generation reaction occurs, and is generated in the first space 12. A gate 14 is provided for the discharge of hydrogen.

In addition, a bellows 24 is attached to the housing 11, and the bellows 24 is connected to the first space 12 so that the upper end of the bellows 24 may be elevated according to the pressure increase or decrease of the first space 12. It is installed to have a second space 25 that is sealed to the outside.

In addition, the reaction rod 20 is coupled to the bottom of the bellows 24 upper end, and the reaction rod 20 is raised and lowered according to the elevation of the bellows 24. Located in one space 12 to coat the hydrogen-producing catalyst layer 21 on the outer peripheral surface of the lower portion. In addition, when the upper end of the bellows 24 is provided with a pressing means to press it downward.

That is, when the metal hydride solution 19 filled in the first space 12 and the hydrogen generating catalyst 21 come into contact with each other, hydrogen is generated to fill the upper portion of the first space 12, increasing the pressure, and increasing the pressure. The hydrogen is moved to the second space 25 through the vent hole 16. Accordingly, as the volume of the second space 25 is expanded by the relaxation of the bellows 24, the reaction rod 20 is raised to block the contact between the hydrogen generating catalyst 21 and the metal hydride solution 19. do.

Therefore, when hydrogen is not used, a constant hydrogen pressure is maintained in the second space 25, so that generation of hydrogen can be restricted, and when the use of hydrogen is required, the bell is opened through the opening of the gate 14. Since the rose 24 is contracted to contact the hydrogen generating catalyst 21 and the metal hydride solution 19, hydrogen may be generated.

However, the above-described conventional hydrogen generators block contact between the fuel solution and the catalyst depending on the elasticity of the spring and the bellows, the characteristics of which can be changed, thereby making it difficult to limit the generation of hydrogen when used for a long time. There was a problem.

Furthermore, if the hydrogen reaction continues to occur due to the spring and bellows elastic changes as described above, there is a concern that the pressure in the fuel tank may continuously increase and lead to an explosion accident. There is also a need for a pressure vessel design of the type.

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above, and provides a portable non-directional hydrogen generator that can safely perform a selective contact action between the catalyst and the fuel solution using a mechanical device for a long time. To provide.

Another object of the present invention is to provide a portable non-directional hydrogen generator that can supply hydrogen to the fuel cell stably regardless of the position of the product through a device capable of collecting hydrogen.

It is still another object of the present invention to provide a portable non-directional hydrogen generator that is configured to couple and detach a fuel tank to simplify replacement and filling of a fuel solution.

The present invention for achieving the above object is, in the apparatus for generating hydrogen by contacting the fuel solution, if necessary, the catalyst coated on the support in order to selectively supply hydrogen to the product of the hydrogen fuel A reaction tube mounted at one side of the fuel cell; A support which is guided and moved inside the reaction tube by a moving means installed at one end of the reaction tube; A fuel tank for accommodating the other end of the reaction tube while being immersed in a fuel solution, wherein the container and the container cover are coupled and separated by a clamping device; It is characterized in that it comprises a hydrogen collecting device for supplying hydrogen generated in the fuel tank to the fuel cell by connecting to each other inside the fuel cell and the fuel tank.

The present invention through the above problem solving means, to control the contact area between the catalyst and the fuel solution through the movement of the support by the drive of the piezoelectric linear motor. That is, the contact between the catalyst and the fuel solution is made mechanically, so that the hydrogen can be freely supplied as much as the user wants, and the hydrogen can be safely generated for a long time.

Particularly, in the present invention, the weight is fixed to the lower surface of the floating body, and by using a long and flexible supply hose, the floating body and the fuel cell are connected to each other so that the floating body always has a hydrogen trapping hole even if the product is located in any direction. It is suspended above the surface of the fuel solution while being held upward. Therefore, hydrogen can be supplied to the fuel cell without limiting the direction of the product, and thus there is an effect that the product can be used freely.

Moreover, the present invention can combine and separate the container cover and the container by the clamping action of the locking wing and the locking piece, there is also an effect that can be replaced and filled with fuel solution more simply and conveniently.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

4 to 8C illustrate the portable non-directional hydrogen generator of the present invention, wherein the reaction tube 100, the support 110, the fuel tank 200, and the hydrogen trap unit are main components. .

4 to 5b, the reaction tube 100 is fixedly mounted to one side of the fuel cell F, and a moving unit that is responsible for the movement of the support 110 is provided at one end of the reaction tube 100. It is provided with a built-in, the other end of the reaction tube 100 is fixed to the sealed chamber 130 of synthetic rubber material so as to maintain the airtight with the fuel solution.

In addition, the support 110 has a rod shape made of Ni, Ti, and SUS (stainless steel), and is provided in the reaction tube 100. Such, the support 110 is guided to the inner surface of the reaction tube 100 by a moving means provided at one end of the reaction tube 100 as described above is moved to the upper or lower.

In this case, a piezoelectric linear motor 140 (Piezo Linear Motor) used in a lens driving device of an advanced camera is used as the moving means. Therefore, the piezoelectric linear motor 140 will be described briefly. By converting the simple vibration of the piezoelectric ceramic, which causes contraction and expansion to be linear motion, when the electric power is applied to the rotary motion, the rotary motor function can be made light and compact. As ultrasonic power is used as the power source, it is characterized by not only noise but also little electromagnetic interference.

Since the piezoelectric linear motor 140 is a known technique used in a conventional camera lens driving apparatus as described above, a detailed configuration description of the piezoelectric linear motor 140 will be omitted.

Subsequently, a catalyst 120 is coated around the support 110. The catalyst 120 is a metal or an oxide capable of generating hydrogen by contact with a fuel solution, and includes Ru, Pt, and Pt-C. Ag, Ni, Ni-B, Rency Ni, Co, Co-B, Co-BO, Pt-LiCoO ₂ and the like are applied.

That is, the support 110 may be moved through the driving of the piezoelectric linear motor 140, and thus the contact area between the catalyst 120 coated on the support 110 and the fuel solution may be adjusted.

On the other hand, the fuel tank 200 is formed in a shape that accommodates a predetermined volume, the container cover 220 and the container 210 is coupled by the clamping device portion is configured to withstand high pressure hydrogen pressure.

The fuel solution is accommodated in the fuel tank 200, and the other end of the reaction tube 100 is tightly inserted into the upper center of the upper end of the container cover 220 mounted on the fuel tank 200. The end part is provided in the state immersed in the fuel solution.

Here, as the fuel solution contained in the fuel tank 200, LiBH ₄ , LiH, NaBH ₄ , LiAlH ₄ , MgH ₂ , NaAlH ₄ , CaH ₂ , KH, KBH ₄ , Ca (BH ₄ ) ₂ , One of various chemical hydrides such as Mg (BH ₄ ) ₂ and KAlH ₄ is selected and dissolved in water to make an aqueous solution.

Subsequently, the clamping device unit coupling the container cover 220 and the container 210 is composed of a locking piece 212, a locking wing 222, and a packing 230.

Referring to FIG. 6, the locking pieces 212 are protruded at equal intervals along the upper circumference of the container 210, and the locking pieces 214 are convexly formed on the lower side of the locking pieces 212. In addition, a plurality of locking wings 222 are provided to be foldable around the container cover 220 corresponding to the position of the locking piece 212, and the locking holes 224 are formed in the center of the locking wings 222, respectively. By fitting the locking piece 212 to the engaging hole 224.

In this case, the packing 230 is mounted around the bottom surface of the container cover 220 which is in contact with the upper surface of the container container 210 so as to maintain the airtightness with the container container 210. Here, the configuration of the clamping device portion is not limited to the above embodiment, if the configuration that can be attached to the container cover 220 and the container 210 to be detachably and included in the configuration of the present invention. will be.

In addition, the size of the container cover 220 and the container 210 can be freely changed according to the shape and size of the product using the fuel cell (F), such matters are also included in the configuration of the present invention.

Next, the hydrogen collecting device unit is connected to each other in the fuel cell F and the fuel tank 200, and serves to supply hydrogen generated in the fuel tank 200 to the fuel cell F, The connection pipe 310, the supply hose 320, the hydrogen collecting hole 330, and the weight 340 is composed of.

4 and 7, the connection pipe 310 is connected between the fuel cell F and one side of the fuel tank 200 to connect the fuel cell F and the fuel tank 200 to each other. In addition, the supply hose 320 is coupled to the end of the connection pipe 310 connected to the fuel tank 200, and the supply hose 320 is provided inside the fuel tank 200.

Then, the floating body 300 is mounted at the end of the supply hose 320 to float the floating body 300 on the surface of the fuel solution. In this case, the floating body 300 can be molded and manufactured with synthetic resin or urethane having chemical resistance, so that the floating body 300 can be suspended in a strong alkaline fuel solution as well as withstand. In addition, the supply hose 320 is provided by using a flexible material of silicone or synthetic rubber while being long, thereby allowing the floating body 300 to float on the surface of the fuel solution regardless of the direction of the product.

Subsequently, a portion of the upper surface of the floating body 300 is formed to penetrate the hydrogen collecting hole 330 to collect hydrogen in the floating body 300, and a center of gravity is disposed on the lower surface of the floating body 300. The weight 340 is fixed to the hydrogen collecting hole 330 without limiting the direction of the product is configured to be floating on the surface of the fuel solution in a state facing upward.

Referring to the operation and effect of the present invention configured as described in detail as follows.

In order to supply hydrogen to a product 80 powered by hydrogen such as a fuel cell F through the portable non-directional hydrogen generator of the present invention, first, the piezoelectric linear motor 140 is driven as shown in FIG. Lower 110).

In this state, the catalyst 120 coated on the outer circumferential surface of the support 110 naturally comes into contact with the fuel solution to generate hydrogen, and as the hydrogen is generated, the pressure inside the fuel tank 200 increases to collect hydrogen. It is collected into the floating body 300 through the hole 330. In addition, the collected hydrogen is moved along the supply hose 320 and the connection pipe 310, so that the labor can be supplied to the fuel cell F.

At this time, when the catalyst 120 comes into contact with the fuel solution as described above, hydrogen is generated and an oxide, which is a reaction residue, is generated. Schemes 1 and 2 below are reaction examples when NaBH ₄ , one of various catalysts 120, is used, and hydrogen is generated by reaction with the catalyst 120 in an aqueous solution in which NaBH ₄ is dissolved in water through the following scheme. It can be seen that NaB (OH) ₄ or NaBO ₂ itself.

NaBH ₄ + 4H ₂ O → 4H ₂ + NaB (OH) ₄

NaBH ₄ + 2H ₂ O → 4H ₂ + NaBO ₂

Meanwhile, when a large amount of hydrogen is required, the support 110 is further lowered by driving the piezoelectric linear motor 140 as shown in FIG. 5B, thereby increasing the contact area between the catalyst 120 and the fuel solution. The hydrogen demand and the hydrogen generation amount coincide.

When the required amount of hydrogen is changed during use of the hydrogen generator of the present invention, the support 110 is raised or lowered by driving the piezoelectric linear motor 140 to contact the catalyst 120 with the fuel solution. Adjust the area. Therefore, it is possible to adjust the amount of hydrogen generated according to the required amount of hydrogen and supply it to the fuel cell (F).

In addition, in order to stop using hydrogen or stop using the product, as shown in FIG. 4, the support 110 is raised by driving the piezoelectric linear motor 140, thereby allowing the catalyst 120 to react with the reaction tube ( It is provided inside to block the contact with fuel solution. Therefore, the contact between the fuel solution and the catalyst 120 is no longer made, whereby the hydrogen generation reaction is stopped. At this time, the bottom of the reaction tube 100 is equipped with a sealed chamber 130, it is possible to closely block the flow of the fuel solution into the reaction tube (100).

On the other hand, the hydrogen generator of the present invention can be used freely without limitation in the direction of the product, as in the use embodiments of Figures 8a to 8c. That is, even if the product is tilted or flipped laterally, since the weight 340 for the center of gravity is fixed to the lower surface of the floating body 300, the floating body (always holding the hydrogen collecting hole 330 upward) 300 can be floated on the surface of the fuel solution.

In addition, the supply hose 320 for connecting between the connection pipe 310 and the floating body 300 is long and made of a flexible material, it is possible to float the floating body 300 on the surface of the fuel solution. . Therefore, it is possible to supply hydrogen to the fuel cell F without limiting the direction of the product, and thus the product can be freely used.

On the other hand, when the fuel solution is exhausted during the use of the hydrogen generator of the present invention when the fuel solution needs to be filled, the container container 210 and the container cover 220 through the clamping release action of the clamping device as shown in FIG. After separation, the fuel solution is filled or the container container 210 is replaced, and the clamping device is clamped again to combine the container container 210 and the container cover 220 to be used.

That is, in order to release the clamping, all of the locking wings 222 are folded upward. Then, while the locking action of the locking hole 224 caught in the locking jaw 214 is released, the locking wing 222 can be separated from the locking piece 212 to the container cover 220 and the container 210 ) Can be separated from each other.

In addition, for the clamping action, the upper surface of the container container 210 and the lower surface of the container cover 220 are brought into contact with each other, while the locking blades 222 and the locking jaw are aligned with each other. It is folded towards the bottom. Then, the locking hole 224 is fitted to the locking jaw 214, the locking wing 222 can be clamped to the locking jaw, the container cover 220 and the container 210 can be coupled to each other. It is. Therefore, when the filling of the fuel solution is required it can be used simply by separating the container 210 and the container cover 220.

On the other hand, the present invention has been described in detail only with respect to the specific examples described above it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, it is natural that such variations and modifications belong to the appended claims. .

1 is a partially cutaway perspective view of a hydrogen generator according to the prior art,

Figure 2a, 2b is a partially cut perspective view for explaining the operating state of the catalytic reaction tube applied to the hydrogen generator according to the prior art,

Figure 3a, 3b is a cross-sectional view showing the structure and operation state of the hydrogen generator according to another prior art,

4 is a cross-sectional view schematically showing the structure of a hydrogen generator according to the present invention;

5A and 5B are cross-sectional views showing a contact state between a catalyst and a fuel solution according to the present invention;

6 is a cross-sectional view showing a separation structure of a fuel tank according to the present invention;

7 is an enlarged cross-sectional view of a buoyancy body according to the present invention;

Figure 8a, 8b, 8c is a state of use carried out by different directions of the product in accordance with the present invention.

* Description of Major Symbols in Drawings *

100: reaction tube 110: support

120 catalyst 130 sealed chamber

140: piezoelectric linear motor 200: fuel tank

210: container 212: locking piece

214: jam jaw 220: container cover

222: locking wing 224: locking hole

230: packing 300: floating body

310: connector 320: supply hose

330: hydrogen collection hole 340: weight

F: fuel cell

Claims (6)

An apparatus for generating hydrogen by contacting a catalyst coated on a support with a fuel solution, if necessary, to selectively supply hydrogen to a product fueled by hydrogen, A reaction tube 100 mounted on one side of the fuel cell F; A support 110 which is guided and moved inside the reaction tube 100 by a moving unit installed at one end of the reaction tube 100; A fuel tank 200 in which the other end of the reaction tube 100 is inserted and received while being immersed in a fuel solution, and the container barrel 210 and the container cover 220 are coupled and separated by a clamping device; It is connected to each other inside the fuel cell (F) and the fuel tank 200, the portable trap characterized in that it comprises a hydrogen collecting device for supplying the hydrogen generated in the fuel tank 200 to the fuel cell (F) Aromatic hydrogen generator. The portable non-directional hydrogen generator according to claim 1, wherein the moving means uses a piezoelectric linear motor (140). The method of claim 1, wherein the clamping device unit, A plurality of locking pieces 212 formed to protrude at equal intervals along the upper circumference of the container barrel 210 and having a locking jaw 214 formed thereon; Locking wings 222 are provided to be folded along the circumference of the container cover 220 corresponding to the position of the locking piece 212, the locking hole 224 is formed in the center to fit the locking piece 212 )Wow; Portable non-directional hydrogen generator, characterized in that it comprises a packing 230 is mounted around the bottom of the container cover 220 to maintain the airtight with the container (210). The method of claim 1, wherein the hydrogen collecting device unit, A connection pipe 310 communicating with the fuel cell F and the inside of the fuel tank 200; A supply hose 320 coupled to an end of the connection pipe 310 and provided in the fuel tank 200; A floating body 300 mounted to an end of the supply hose 320 and floating on an upper surface of the fuel solution; A hydrogen collecting hole 330 formed through a portion of the upper surface of the floating body 300; Portable non-directional hydrogen generator, characterized in that it comprises a weight (340) fixed to the inner bottom surface of the floating body (300). 5. The portable non-directional hydrogen generator according to claim 4, wherein the supply hose (320) uses silicon or synthetic rubber of a flexible material. [5] The portable non-directional hydrogen generator of claim 4, wherein the floating body is made of synthetic resin or urethane having chemical resistance.

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