TWI676715B - Method and device for remelting hydrogen molecules in a circular disk type electrolytic cell - Google Patents

Abstract

A method and a device for remelting hydrogen molecules of a disc-shaped electrolytic cell, especially referring to a gas collecting water guide plate and an electrode plate inside the base body and the cover body respectively, and an ion membrane is arranged between the two electrode plates. The base and the cover are respectively provided with an air-collecting and water-conducting chamber corresponding to the two air-collecting water guide plates, a water inlet is provided at the center of the two electrode plates, and a plurality of hollow and radiating configurations are arranged at the corresponding positions of the two electrode plates In the anode and anode chambers, raw water flows into the anode and anode chambers from the water inlets of the two electrode plates. The hydrogen and oxygen molecules generated after electrolysis are taken away from the cathode and anode chambers by the cathode water and the anode water, respectively. The second gas-conducting water-conducting chamber allows hydrogen molecules to interact with the cathode water in the gas-conducting water-conducting chamber. At the same time, it cooperates with pressure to force more hydrogen molecules to dissolve into the cathode water again, thereby increasing the concentration of hydrogen molecules in the cathode water. By.

Description

Method and device for remelting hydrogen molecules of disk-shaped electrolytic cell

The method and device for re-dissolving hydrogen molecules of the disc-shaped electrolytic cell of the present invention are mainly applied to the technology for increasing the total dissolved amount of hydrogen molecules (including negative hydrogen ions) in electrolytic reduction water.

In recent years, hydrogen molecular medicine has become a new hotspot in preventive medicine research. At present, there are various animal disease modes such as inhaling hydrogen gas or injecting hydrogen physiological food water, which has proved its protective and alleviating effect. Sexually safe gas is also the smallest antioxidant in the universe. Because of its ability to eliminate free radicals from all diseases, experts and scholars around the world have invested in research and published papers and clinical evidence to confirm that hydrogen molecules are important for health, beauty and Disease prevention has a good effect, and it is predicted that a new milestone for hydrogen molecular medicine will start in the future!

Although the functional research and pathological mechanism of hydrogen molecules have gradually become clear, since the above-mentioned inhaled hydrogen gas or injectable hydrogen physiological food water requires professional technology and equipment, it will be economical and convenient if hydrogen molecules can be introduced into daily drinking water. The health care method is expected to bring new dawn to people's health industry and new hope for the hydrogen industry.

However, there are still many problems that need to be overcome in terms of hardware. The traditional electrolysis equipment includes: traditional flowing-type porous electrolytic cell, standing type hydrogen water electrolytic cup and porous flowing-type electrolytic cell. Very low, causing normal electricity The total dissolved amount of hydrogen molecules in the electrolytic reduction water generated by the decomposition equipment is insufficient. The following is a description of the problems caused by the above three conventional electrolytic cells: The electrode design of the traditional flowing-type porous electrolytic cell is mostly composed of round, square, rectangular or mesh electrodes. The water flow channels are all arranged on the surface of the electrode plate, so that a large number of recesses appear in the vertical section of the electrode aperture to form a "stagnant area". The so-called "stagnation area" is the area where the water flows slowly. This area will cause agglomeration of the hydrogen generated by the cathode, and then generate larger bubbles. In other words, the hydrogen just generated by the cathode cannot be quickly dissolved in water, which will reduce the amount of hydrogen molecules dissolved in the cathode water.

Aiming at the horizontal installation of the electrolytic tank, the static water electrolyzed water electrolyzed cup is taken as an example. Currently, the main problem is that because the mass of the gas is lighter than that of water, no matter hydrogen or oxygen, it has the physical property of light rise. :

First, the hydrogen (hydrogen molecules or negative hydrogen ions) generated above the cathode will form bubbles due to agglomeration, and quickly rise above the water cup, so that the hydrogen generated by the cathode is not completely dissolved in the water, which causes the The content of hydrogen molecules in the water cup is insufficient.

Second, the oxygen generated under the anode cannot be smoothly exported due to insufficient pressure above it, so it often stagnates in the hole (vertical section) below the anode. This phenomenon will cause the electrode impedance to increase rapidly.

3. The electrolyte required under the anode (that is, in the anode chamber) is introduced into the anode chamber from the upper side of the cathode, that is, in the cup, through a hole or a hydrophilic ion membrane. The holes actually pass through the cathode and anode chamber Room, so the following contradiction occurs, which is when the hole Too small, the upper electrolyte is not easy to be introduced into the lower anode chamber. If the holes are too large, it is easy to conduct water, but the oxygen and ozone generated by the lower anode are also easy to rise and mix into the upper cathode water to cause pollution. If the electrode solution required in the anode chamber is introduced by means of a hydrophilic ion membrane, it will take a long time to soak due to the impedance of the membrane, so that the ion membrane above the anode chamber can be sufficiently wet. , So often cause the water cup to electrolyze for a period of time (about ten minutes or more), you must rest. This phenomenon prevents the water cup from continuously generating hydrogen water (hydrogen-rich water), which is the biggest drawback.

The electrodes of the conventional porous flow-type electrolytic cell are mostly erected vertically, that is, the electrode design is in a left-right configuration. The water flow method is from bottom to top, that is, the water is designed below the electrolytic cell, and the water is designed for electrolysis. Above the tank, as described above, when the gas leaves the electrode, it has the physical properties of a light rise that will quickly move from bottom to top with the water flow. The hydrogen that is not dissolved in the cathode chamber will be quickly taken out, which is mainly due to the It is difficult to set the air holding space on the left and right sides of the electrode. Generally, the cathode water is led out of the electrolytic cell body and then introduced into a specially designed air holding chamber to increase the hydrogen molecule capacity. The above structure mainly makes up for the inadequacy of the traditional electrolytic cell. However, it only increases the space problem and increases the structural cost, which is the existing problems and shortcomings that need to be solved.

The inventor is currently engaged in the manufacture and design of related products, and has accumulated many years of practical experience and knowledge. In response to the existing problems and deficiencies of the conventional electrolytic cell, he actively invested in the spirit of innovation and improvement. Method and device for remelting hydrogen molecules in tank.

The technical means applied to solve the problem of the present invention and the effect of comparing with the prior art are as follows: firstly, the hydrogen content in the cathode water has not been completely dissolved in the electrolytic reduction water; In addition, through the phenomenon of dissolution, it cooperates with multiple annular hydrogen-dissolving chambers and increases the pressure to force more hydrogen molecules to re-dissolve in water.

The technical means applied to solve the second problem of the present invention and the second effect of comparing with the prior art are: the ring-shaped anode and cathode plates are cut into radial holes to form a cathode and anode chamber, and the cathode and anode chambers also constitute a cathode and anode water flow Therefore, the initial ecological hydrogen can be quickly taken away from the cathode chamber, avoiding the phenomenon of hydrogen agglomeration and generating larger bubbles, which can effectively increase the amount of hydrogen dissolved.

The technical means applied to solve the third problem of the present invention and the three effects compared with the previous technology are: a gas collecting and conducting chamber is arranged under the anode electrode plate, so as to quickly store the oxygen and ozone generated by the anode electrode plate and avoid the oxygen and ozone Mixed into the upper cathode water, experiments have proved that the above measures can effectively increase the amount of hydrogen molecules dissolved in the cathode water and ensure the purity of hydrogen molecules in the cathode water.

10‧‧‧ seat

11‧‧‧ socket projection

111‧‧‧ trench

112‧‧‧ Tongue

12‧‧‧ divider

121‧‧‧Anode water flow path

13‧‧‧ perforation

14‧‧‧ conductive spacer

141‧‧‧internal thread

15‧‧‧Raw water inlet ring

151‧‧‧ rib

152‧‧‧Raw water inlet flow path

16‧‧‧Anode water outlet ring

161‧‧‧ rib

162‧‧‧Anode water outlet channel

163‧‧‧Anode water outlet

164‧‧‧Anode water outlet hole

17‧‧‧ flange

171‧‧‧Combination slot

18‧‧‧ male thread

19‧‧‧ Trench

20‧‧‧Conductor

21‧‧‧external thread

22‧‧‧ Positioning step margin

23‧‧‧external thread

24‧‧‧ Positioning edge

25‧‧‧ Trench

26‧‧‧Conductive section

30‧‧‧lower gas collection water guide plate

31‧‧‧hole post

311‧‧‧fisheye

32‧‧‧Raw water inlet ring

321‧‧‧Groove

33‧‧‧ raw water inlet

34‧‧‧ raw water inlet tank

35‧‧‧Positioning slot

36‧‧‧Anode water outlet

361‧‧‧Anode water outlet channel

362‧‧‧ convex ring

37‧‧‧Trench

38‧‧‧ flange

39‧‧‧Border

391‧‧‧Gathering water guide room

40‧‧‧Anode electrode plate

41‧‧‧shaft hole

42‧‧‧Anode chamber

43‧‧‧ water inlet

44‧‧‧Positioning Department

45‧‧‧Positive Conductor

46‧‧‧ male thread

50‧‧‧ion membrane

51‧‧‧ round hole

60‧‧‧ cathode electrode plate

61‧‧‧Shaft hole

62‧‧‧cathode chamber

63‧‧‧Inlet

64‧‧‧Positioning Department

70‧‧‧ Upper gas-conducting tray

71‧‧‧ positioning block

72‧‧‧ Trench

73‧‧‧ receiving groove

74‧‧‧ raw water inlet tank

75‧‧‧ cathode water outlet

76‧‧‧ cathode water outlet channel

77‧‧‧Ring ring

78‧‧‧Gas-collecting water-conducting chamber

79‧‧‧ gap

80‧‧‧ Cover

81‧‧‧internal thread

82‧‧‧ circular ring

83‧‧‧Hydrolysis room

84‧‧‧ gap

85‧‧‧ cathode water outlet connector

86‧‧‧Trench

90‧‧‧ water inlet and outlet

91‧‧‧ hollow shaft

92‧‧‧ socket recess

93‧‧‧Dovetail

94‧‧‧Anode water outlet tank

95‧‧‧ raw water inlet tank

96‧‧‧Anode water outlet connector

97‧‧‧ raw water inlet connector

98‧‧‧ negative conductive column

99‧‧‧ Positive conductive sheet

S‧‧‧elastic element

R‧‧‧ Gasket

N‧‧‧nut

Q‧‧‧Waterproof washer

The first figure is a bottom view stereo combination diagram of the first embodiment of the present invention.

FIG. 2 is a front sectional view of a three-dimensional combination of Embodiment 1 of the present invention.

FIG. 3 is a three-dimensional sectional view of a seat body and a lower air-collecting water guide plate according to the first embodiment of the present invention.

The fourth figure is a three-dimensional exploded view and an enlarged schematic view of the A part, the K part, and the G part in the first embodiment of the present invention.

Fifth figure: It is a three-dimensional exploded view and an enlarged schematic view of the S part according to the first embodiment of the present invention.

FIG. 6 is a schematic sectional view of the conductive state of the cathode and anode electrode plates according to the first embodiment of the present invention.

The seventh figure is a schematic enlarged view of a cross-section combination of raw water entering into C and Y sections during electrolysis according to the first embodiment of the present invention.

Figure 8: Schematic diagram of E-E cross section of Figure 7.

The ninth figure is a schematic diagram of a sectional combination of cathode water and anode water derived during electrolysis according to the first embodiment of the present invention.

Fig. 10: Schematic diagram of J-J cross-section combination of Fig. 9.

Figure 11: Schematic diagram of the F-F cross-section combination of Figure 9.

Figure 12: Schematic diagram of R-R cross-section combination of Figure 9.

Figure 13: A three-dimensional exploded view of Embodiment 2 of the present invention.

Fig. 14 is a schematic sectional view and enlarged view of part H in the second embodiment of the present invention.

In order to make it easy for people who are familiar with this technology to understand the construction content of the present invention and the functional benefits that can be achieved, a specific embodiment is listed, and the details are described in conjunction with the drawings as follows: a disc-shaped electrolytic cell For the method and device for re-melting hydrogen molecules, please refer to the first to fifth figures. It mainly includes: a body 10, a conductive body 20, a lower gas collection water guide plate 30, an anode electrode plate 40, an ion membrane 50, a cathode electrode plate 60, an upper gas collection water guide plate 70, a cover 80, a Inlet and outlet water connector 90 and a plurality of water-proof washers Q; The base body 10 has a disc shape. A hollow socket convex portion 11 is extended downward from the center of the base body 10 as a socket for a water inlet and outlet joint 90. The socket convex portion 11 is provided with two grooves on the outside. The groove 111 is sealed by two water-stop washers Q. Two tenon heads 112 are provided on the outside of the socket convex portion 11 for fixing a water inlet and outlet joint 90. The top surface of the base body 10 is provided with a plurality of equal divisions. The partition plates 12 are arranged in a radial pattern, and an anode water flow path 121 is formed between each of the partition plates 12. Two perforations 13 are provided on both sides of the top surface of the base body 10, as two of the anode electrode plate 40. The positive electrode conductive portion 45 is used for penetration, and is locked and fixed on the base 10 by two gaskets R and two nuts N. The sleeve convex portion 11 is sequentially provided with a conductive partition tube 14 and Raw water inlet ring 15 and an anode water outlet ring 16. The conductive partition tube 14 is provided with an internal thread 141 for locking a conductor 20. The inner wall of the raw water inlet ring 15 is electrically conductive. A plurality of equally divided ribs 151 are provided between the partition pipes 14, so that a raw water inlet flow path 152 is formed on the inner wall of the raw water inlet ring 15, and the anode water outlet ring 16 A plurality of equally divided ribs 161 are provided between the inner wall and the raw water inlet ring 15 to form an anode water outlet channel 162 on the inner wall of the anode water outlet ring 16. The anode water outlet ring 16 corresponds to An anode water outlet 163 is provided at the anode water flow path 121, and a plurality of equally divided anode water outlet holes 164 are provided at the bottom of the anode water outlet flow path 162 corresponding to the circumferential periphery of the socket convex portion 11. The base body 10 A top surface corresponding to the periphery of the plurality of partition plates 12 is provided with a ring of flanges 17 so as to form a coupling groove 171 between the inner wall of the base body 10 and the flanges 17 for the purpose of combining the air collection water guide plate 30. The outer wall of the base body 10 is provided with an external thread 18 corresponding to the inner wall of the cover body 80 as the base body 10 and the cover body 80 are locked against each other. The base body 10 corresponds to A ring of groove 19 is provided above the external thread 18, which can be used to press a water-proof washer Q as the base 10 and the cover 80 to lock the water when they are locked against each other; the upper end of the conductive body 20 is provided with an external thread 21 and a positioning step 22 can be used to lock a water tight washer Q and a nut N at the center of the cathode electrode plate 60. The lower end of the conductive body 20 is provided with an external thread 23 and a positioning step 24 for Locked in the internal thread 141 of the conductive partition tube 14 in the center of the base body 10, a groove 25 is formed between the two positioning step edges 22 and 24, and a water-proof gasket Q can be pressed to stop the water. The conductive body 20 A conductive part 26 is provided at the lower end; the lower air-collecting water guide plate 30 is disc-shaped, and the lower air-collecting water guide plate 30 is provided with two-hole posts 31 at the two perforations 13 of the base 10, and the two-hole posts 31 The outer diameter is equivalent to the inner diameter of the second perforation 13, so that the two-hole pillar 31 can pass through the second perforation 13. The inside of the two-hole pillar 31 is provided with two fish-eye holes 311 for the anode electrode plate 40. Two positive electrode conductive parts 45 pass through, and two water-stop washers Q are provided above the two fish-eye holes 311 for water-stopping. A raw water is provided at the center of the lower air-collecting water guide plate 30. Water inlet spacer 32. The raw water inlet spacer 32 is provided with a plurality of raw water inlets 33 on the circumference of the outer wall. The raw water inlet 33 is provided with a circle of raw water inlet groove 34 at the periphery of the raw water inlet 33, so that raw water can be removed from the plural. Each raw water inlet 33 enters the raw water inlet tank 34, and then flows out from the raw water inlet tank 34 in a radiating manner from the inside to the outside. The circumferential inner wall of the top surface of the lower air collection water guide plate 30 is provided with a plurality of equally positioned positioning grooves 35. As the upper air-collection water guide plate 70 is embedded for setting, a plurality of equally divided anode water outlets 36 are provided at the peripheral periphery of the top surface of the lower air-collection water guide 30, and the inner circumference of the anode water outlet 36 A plurality of anode water outlet channels 361 are provided. A ring of convex rings 362 are provided around the periphery of several anode water outlets 36 to stop the water of the ion membrane 50. The lower part of the raw water inlet ring 32 corresponds to the inner wall of the raw water inlet ring 15 of the base 10. There is a circle of grooves 321 for pressing a water-stop washer Q to stop water. The outer wall of the lower air-collecting water guide plate 30 corresponds to the inner wall of the coupling groove 17 of the base body 10. A water stop washer Q is pressed to stop water to prevent the cathode water from being mixed with the anode water. The top surface of the lower air collection water guide plate 30 is provided with a ring of flanges 38 at the circumference corresponding to the plurality of anode water outlets 36. The flange 38 is used. Raise the water level of the anode water to allow the ion membrane 50 to be sufficiently wet. The bottom surface of the lower gas-collecting water guide plate 30 corresponds to a plurality of anode water outlets 36, and a circle of blocking edges 39 is provided around the circumference to thereby collect gas in the lower gas-collecting area. A gas-collecting and water-conducting chamber 391 is formed on the bottom surface of the water guide plate 30 for oxygen molecular gas collection and anode water-conducting, so as to quickly store the oxygen and ozone generated by the anode electrode plate 40 to prevent the oxygen and ozone from being mixed into the upper cathode water; The anode electrode plate 40 has a disc shape. A shaft hole 41 is provided. The inner diameter of the shaft hole 41 is equivalent to the outer diameter of the raw water inlet ring 32 of the lower gas-collecting water guide plate 30. The anode electrode plate 40 is provided with a plurality of hollow and radiating holes on its circumferential surface. The anode chamber 42 may be V-shaped, so that a plurality of water inlets 43 are formed at the raw water inlet tank 322 corresponding to the lower air guide plate 30, so that raw water can be introduced from the plurality of water inlets 43. In the plurality of anode chambers 42, a plurality of positioning portions 44 which are equally divided and recessed are provided at the peripheral periphery of the anode electrode plate 40 for guiding when aligning with the cathode electrode plate 60. The electrode plate 40 is provided with two positive electrodes corresponding to the two perforations 13 of the base 10 and the two fish-eye holes 311 of the lower air-collecting water guide plate 30. Conductive portion 45. The two positive conductive portions 45 are provided with two external threads 46 for locking the nut N. A circular hole 51 is provided in the center of the ion membrane 50. The inner diameter of the circular hole 51 and the lower gas-collecting and water-conducting portion The inner diameter of the raw water inlet spacer 32 of the disk 30 is equivalent. The ion membrane 50 can be a proton exchange membrane. The outer diameter of the ion membrane 50 is larger than the outer diameters of the anode electrode plate 40 and the cathode electrode plate 60. The hydrogen molecules can be allowed during electrolysis. It penetrates the ion membrane 50, but oxygen molecules cannot penetrate the ion membrane 50, which can prevent the oxygen and ozone generated by the anode electrode plate 40 from being mixed into the upper cathode water; the cathode electrode plate 60 has a disc shape, and the cathode electrode plate 60 A shaft hole 61 is provided in the center. The inner diameter of the shaft hole 61 is equivalent to the outer diameter of the external thread 21 at the upper end of the conductor 20. After the external thread 21 at the upper end of the conductor 20 passes through the shaft hole 61 of the cathode electrode plate 60, A water stop washer Q and a nut N are locked at the center position of the cathode electrode plate 60. The circumferential surface of the cathode electrode plate 60 is provided with a plurality of hollow cathode chambers 62 which are arranged in a radial shape. The shape of the chamber 62 may be a V-shape. The anode chamber 42 of the anode electrode plate 40 is electrically connected to the cathode. The shape, size and position of the cathode chamber 62 of the plate 60 are completely the same. The cathode electrode plate 60 is provided between the shaft hole 61 and the plurality of cathode chambers 62. It can be introduced into a plurality of cathode chambers 62 from a plurality of water inlets 63. A plurality of positioning portions 64 that are arranged in an equally divided and concave shape are provided at the periphery of the cathode electrode plate 60. The positioning portion 44 is used to align and guide, so that the anode chamber 42 of the anode electrode plate 40 and the cathode chamber 62 of the cathode electrode plate 60 can completely match; The upper air-collection water guide plate 70 has a disc shape. The upper air-collection water guide plate 70 corresponds to the plurality of positioning cavities 35 of the lower air-collection water guide plate 30. A plurality of positioning inserts 71 are provided as the upper air-collection water guide plate. 70 and the lower air-collection water guide plate 30 are embedded for setting. The upper air-collection water guide 70 corresponds to the convex ring 362 of the lower air-collection water tray 30 and is provided with a groove 72 for pressing a water-proof gasket Q. Let the ion membrane 50 form a water-stopping effect when the water-stop washer Q of the upper air-collection water guide plate 70 and the convex ring 362 of the lower air-collection water guide plate 30 are pressed against each other to prevent the cathode water and the anode water from mixing. An accommodating groove 73 is provided at the center of the bottom surface of the upper air-collection water guide plate 70 to receive the external thread 21 and the nut N at the upper end of the conductor 20. The bottom surface of the upper air-collection water guide plate 70 corresponds to the cathode electrode plate 60. A plurality of raw water inlet troughs 74 are provided at the plurality of water inlets 63, so that raw water can enter the raw water inlet troughs 74 from the multiple raw water inlets 63, and then radiate out from the raw water inlet troughs 74 from the inside to the outside. A plurality of equally-divided cathode water outlets 75 are provided at the periphery of the plate 70, and the upper gas-collecting water guide plate 70 is at the bottom Corresponding to the circumference of the plurality of cathode water outlets 75, a plurality of equally divided cathode water outlet channels 76 are provided. The top surface of the upper air-collection water guide plate 70 corresponds to the circumference of the plurality of cathode water outlets 75. A plurality of annular retaining edges 77 are provided thereon to form a plurality of air collecting and guiding chambers 78 on the top surface of the upper gas collecting water guide plate 70. A plurality of notches 79 are provided on the top surface of the plurality of annular retaining edges 77. As the hydrogen molecular gas collection and the cathode water conducting water, the hydrogen generated by the cathode electrode plate 60 is quickly stored; the inner wall of the cover 80 corresponds to the external thread 18 of the base body 10 and is provided with an internal thread 81 as a cover The body 80 and the base body 10 are used to lock each other. The cover body 80 corresponds to a plurality of circular ring-shaped retaining edges 77 on the upper air-collecting water guide plate 70 and intersects each other. The staggered annular baffle 82 forms a plurality of hydrogen-dissolving chambers 83 at the upper position inside the cover body 80. The top surfaces of the plurality of annular baffles 82 are provided with a plurality of gaps 84 as hydrogen molecules. The use of gas collection and cathode water to conduct water allows the cathode water to flow continuously up and down in the plurality of gas collection and drainage chambers 78 and the plurality of hydrogen dissolving chambers 83. It uses the rising of hydrogen to interact with the falling of the cathode water. This phenomenon causes more hydrogen molecules to dissolve into the water. The center of the cover 80 is provided with a cathode water outlet connector 85 extending upward and penetrating. The cathode water outlet connector 85 is provided with a circle of grooves 86 on the outside for pressure placement. A water stop washer Q is used to connect a cathode water outlet hose (not shown), so that cathode water rich in active hydrogen can be passed from the cathode water outlet connector 85 and the cathode water outlet hose (not shown) ) Lead; the center of the water inlet and outlet connector 90 corresponding to the conductive partition tube 14 of the base body 10 is provided with a hollow shaft column 91, the hollow shaft column 91 is provided with an elastic element S and a negative conductive column 98 (please refer to section (Shown in Figure 6), using the elastic force of the elastic element S, let the negative electrode The upper end of the conductive post 98 can be in close contact with the conductive part 26 of the conductive body 20. The lower end of the conductive post 98 can be connected to a negative wire (not shown). The top surface of the water inlet and outlet connector 90 corresponds to the anode electrode plate. The two positive electrode conductive portions 45 of 40 are provided with elastic two positive electrode conductive pieces 99 (see the sixth figure), so that the lower ends of the two positive electrode conductive portions 45 of the anode electrode plate 40 can be in close contact with the two positive electrode conductive pieces. 99, the lower end of the two positive conductive pieces 99 can be connected to a positive electric wire (not shown in the figure), and the water inlet and outlet connector 90 is provided with a set of connecting recesses 92 at the socket convex portion 11 of the base body 10, and the base body The outer diameter of the socket convex portion 10 of 10 is equivalent to the inner diameter of the socket concave portion 92 of the water inlet and outlet joint 90. The socket concave portion 92 is provided with a two tongue groove 93 at the two tongue 112, so that the two tongue 112 can be screwed in or screwed. Out of Two mortise grooves 93 are used to quickly assemble or disassemble the water inlet and outlet joints 90. The socket recess 92 is provided coaxially with an anode water outlet tank 94 and a raw water inlet tank 95. The anode water outlet tank 94 has an inner diameter larger than that of the raw water. Water inlet tank 95, the outside of the water inlet and outlet connector 90 corresponding to the anode water outlet tank 94 is provided with an anode water outlet connector 96, and the anode water outlet connector 96 can be used to lead an anode water outlet hose (not shown), A raw water inlet connector 97 is provided on the outside of the water inlet and outlet connector 90 corresponding to the raw water inlet tank 95.

The present invention, which is formed by combining the above-mentioned element structures, is to provide a method and a device for re-dissolving hydrogen molecules of a disk-shaped electrolytic cell. In actual operation and application: please refer to the seventh figure: Embodiment 1 of the invention The enlarged sectional view of the combination of the cross section of the raw water entering during electrolysis and the C and Y sections. It is shown in Figure 8 with the E-E cross-section of Figure 7. When raw water flows in, raw water is introduced into the raw water inlet tank 95 from the raw water inlet joint 97 of the water inlet and outlet joint 90, and the raw water inlet flow path 152 formed by the inner wall of the raw water inlet spacer 15 of the base 10 flows in from bottom to top. Most of the water is introduced into the raw water inlet groove 74 of the upper gas collecting pan 70 through the plurality of water inlets 63 of the cathode electrode plate 60, and then flows into the cathode electrode plate 60 in a plurality of cathode chambers in a radial configuration from the raw water inlet groove 74. 62. A small part of the water flows into the raw water inlet tank 34 from a plurality of raw water inlet ports 33 around the raw water inlet ring 32 of the lower gas guide pan 30, and then enters from the raw water inlet tank 34 through the anode electrode plate 40. The nozzle 43 flows into a plurality of anode chambers 42 arranged in a radial pattern.

Please refer to the ninth figure, which is a schematic diagram of a sectional combination of cathode water and anode water derived during electrolysis according to the first embodiment of the present invention. And the tenth, eleventh, and twelve pictures: the ninth picture J-J, F-F and R-R sectional combination diagram. When the raw water is electrolyzed, the raw water is electrolyzed in the plurality of cathode chambers 62 of the cathode electrode plate 60 and the plurality of anode chambers 42 of the anode electrode plate 40, thereby generating hydrogen and cathode water in the plurality of cathode chambers 62, and The plurality of anode chambers 42 generate oxygen, ozone, and anode water. Since the cathode electrode plate 60 and the anode electrode plate 40 are separated by a layer of ion membrane 50, hydrogen molecules can penetrate the ion membrane 50 during electrolysis, but oxygen molecules cannot pass through. The ion-permeable membrane 50 can prevent oxygen and ozone generated from the anode electrode plate 40 from being mixed into the upper cathode water. The initial ecological hydrogen generated in the cathode chamber 62 is rapidly dissolved and carried away by the cathode water. The cathode water outlet channel 76 of the upper gas guide plate 70 flows into the cathode water outlet 75, and then the cathode water outlet 75. From the bottom to the top, the gap 79 of the annular annular flange 77 is introduced into the upper gas collection water guiding chamber 78, so that hydrogen molecules can be collected above the hydrogen dissolving chamber 83, and the cathode water is allowed to pass through the plurality of gas collection water guiding chambers 78 and The plurality of hydrogen-dissolving chambers 83 have a continuous S-shaped flow from top to bottom and up and down. Using the mutual dissolving phenomenon caused by the rise of hydrogen and the decline of cathode water, more hydrogen molecules are dissolved in the water, and more hydrogen molecules are dissolved again with the pressure. In the cathode water, the concentration of hydrogen molecules in the cathode water is increased, and finally the cathode water rich in hydrogen molecules can be exported from the cathode water outlet connector 85 and the cathode water outlet hose (not shown), and the anode chamber 42 generates The oxygen and ozone are quickly carried away by the anode water, and then flow into the anode water outlet 36 through the anode water outlet channel 361 of the lower gas collecting water guide 30, and then from the anode water outlet 36 from the top to the bottom 39. Into the air-collecting and water-conducting chamber 391 below, Oxygen and ozone can be quickly stored above the gas collection water guiding chamber 391 to prevent the oxygen and ozone from being mixed into the upper cathode water. The anode water is used to remove oxygen and ozone from the anode water collection tank 94 and the anode water outlet 96 of the inlet and outlet water connector 90. versus The anode water outlet hose (not shown) is discharged, and the flange 38 is used to raise the anode water level, so that the ion membrane 50 is sufficiently wet.

The hydrogen molecule remelting device of the disc-shaped electrolytic cell provided by the present invention, please refer to the thirteenth figure, which is a three-dimensional exploded view of the second embodiment of the present invention. It is shown in the fourteenth figure: a sectional combination and an enlarged schematic view of the H part in the second embodiment of the present invention. Wherein, the anode chamber 42 of the anode electrode plate 40 and the cathode chamber 62 of the cathode electrode plate 60 can also be made porous. The lower air-collection water guide plate 30 and the upper air-collection water guide plate 70 correspond to the porous type. The anode chamber 42 and the cathode chamber 62 are provided with a plurality of partition ribs 341 and 741 arranged in a radial pattern, thereby forming a plurality of anode water channels 342 and a cathode water channel 742 between the plurality of partition ribs 341 and 741, respectively. The oxygen and ozone generated by the porous anode chamber 42 can be quickly taken away by the anode water, and the cathode chamber 62 is used to rapidly dissolve the initial ecological hydrogen generated by the porous cathode chamber 62 by using cathode water. Mergers and departures.

In summary, the method and device for remelting hydrogen molecules of the disc-shaped electrolytic cell provided by the present invention have been actually manufactured, and it has been proved that the total amount of hydrogen molecules dissolved in the cathode water can be effectively increased by more than 30%. In addition, the present invention combines the hydrogen-dissolving chamber and the gas-collecting chamber into a complete and modularized module. In addition to reducing costs, it can also be quickly assembled and disassembled, which has the advantage of being convenient for sales and service. It is expected that it will contribute to the hydrogen industry in the future. At the same time, it is the first creation that has not been heard in the field, and has industrial value. It certainly meets the essentials of the utility and advancement of invention patents. According to the provisions of the Patent Law, it has filed an application for invention patents with the Bureau.

Claims (16)

A method for remelting hydrogen molecules of a disc-shaped electrolytic cell, which mainly introduces raw water from a water inlet in the center of a two-electrode plate, and flows out in a radial shape along the cathode and anode chambers corresponding to the two-electrode plate, so that the cathode water It has a dissolving effect with the original ecological hydrogen molecules. An ionic membrane is arranged between the two electrode plates to prevent the oxygen molecules generated after electrolysis from being mixed into the cathode water. At the same time, the hydrogen molecules and oxygen molecules are carried away by the cathode water and the anode water. The cathode and anode chambers are respectively introduced into the upper and lower gas-collecting and water-conducting chambers, so that the hydrogen molecules and the cathode water re-dissolve in the gas-collecting and water-conducting chambers, forcing more hydrogen molecules to dissolve into the cathode water again, thereby increasing the cathode. The concentration of hydrogen molecules in water. A hydrogen-molecule remelting device for a disc-shaped electrolytic cell is mainly composed of a disc-shaped electrolytic cell composed of a disc-shaped base and a lid body, which are assembled with two gas-collecting water guide plates, two negative anode electrode plates, and an ion membrane. A water inlet and outlet connector is provided on the outside of the base body. Among them: an air collection water guide plate and an anode electrode plate are arranged above the base body, and a water inlet and outlet connector is extended downward from the center of the base body; A gas collecting water guide plate and a cathode electrode plate are arranged at the lower part, a cathode water outlet connector is extended upward at the center of the cover body, and a plurality of rings arranged alternately are arranged between the cover body and the gas collecting water guide plate. The retaining edge is formed so that a plurality of hydrogen-dissolving chambers are formed at the upper position inside the cover body. The plurality of annular retaining edges are provided with a plurality of gaps for the hydrogen molecular gas collection and the cathode water to conduct water, so that the cathode water A continuous S-shaped flow can be provided above and below the plurality of gas-conducting water-conducting chambers and the plurality of hydrogen-dissolving chambers, and the use of the mutual dissolution phenomenon caused by the rise of hydrogen and the decline of the cathode water allows more hydrogen molecules to dissolve into the water; Correspondence to air guide plate Two air-collecting and water-conducting chambers are provided above the base body and below the cover body; a water inlet is provided in the center of the two negative anode electrode plates, and a plurality of hollow and radiating shapes are provided on the corresponding surfaces of the two negative anode electrode plates. The configured anode and cathode chamber; the ion membrane is arranged between the two anode anode electrode plates; the water inlet and outlet joints are provided with a raw water inlet joint and an anode water outlet joint; raw water is respectively introduced from the water inlet of the two anode anode electrode plate In the cathode and anode chambers, the hydrogen and oxygen molecules generated after electrolysis are separated by the cathode water and the anode water, and are respectively introduced into the upper and lower gas-collecting water-conducting chambers, so that the hydrogen molecules and the cathode water are in the gas-conducting water-conducting chamber. Produces a dissolution effect, forcing more hydrogen molecules to dissolve in the cathode water again, thereby increasing the concentration of hydrogen molecules in the cathode water. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein the polarities of the two negative anode electrode plates are interchangeable. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein: the top surface of the base body is provided with a plurality of equally divided partition plates arranged in a radial pattern, and at the same time, An anode water flow path is formed therebetween. The center of the base body is provided with a conductive partition tube, a raw water inlet ring and an anode water outlet ring in order from the inside to the outside. The inner wall of the raw water inlet ring is electrically conductive. A plurality of equally divided ribs are provided between the tubes, thereby forming a raw water inlet flow path on the inner wall of the raw water inlet ring, and a plurality of spaces are provided between the inner wall of the anode water outlet ring and the raw water inlet ring An equal number of ribs are formed on the inner wall of the anode water outlet ring to form an anode water outlet flow path. The anode water outlet ring is provided with an anode water outlet at the anode water flow path. The anode water outlet flow path A plurality of aliquots of anode water outlet holes are provided at the peripheral periphery of the bottom. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein: a circle of flange is provided at the inner circumference of the top surface of the base body, so that the inner wall of the base body and the flange A combination groove is formed between the two to serve as a gas collection water guide plate. The outer wall of the gas collection water guide plate is provided with a circle of grooves corresponding to the combination groove, which can be used to press a water stop washer water to prevent the cathode water and anode water from mixing. By. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein: a set of convex portions is extended downward at the center of the base body, and a set of concave portions is provided at the center of the water inlet and outlet joints, A tenon and a tenon groove are provided at the corresponding positions of the socket convex portion and the socket concave portion, so that the water inlet and outlet joints can be fastened to the seat body. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein the base body and the cover body are provided with corresponding external and internal threads, and the base body and the cover body are interlocked with each other. Users. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein: the periphery of the two negative anode electrode plates is provided with a plurality of positioning portions arranged in equal divisions as the two negative anode electrode plates The use of alignment guides allows the cathode and anode chambers of the two cathode anode plates to completely correspond to the anastomosis. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein the ion membrane can be a proton exchange membrane, the outer diameter of the ion membrane is larger than the outer diameter of the two electrode plates, and the two gas-collecting and water-conducting channels Corresponding convex rings and grooves are provided at the outer circumference of the disc, and the grooves can be used to press a water-proof gasket, so that the ion membrane is formed under the mutual pressure of the convex rings and the water-proof gasket of the two gas-collecting water guide plates. Water-stopping effect can avoid the mixed flow of cathode water and anode water. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein: a plurality of positioning cavities and positioning cavities are provided at the corresponding positions on the circumference of the two gas-collecting water guide plates as the two gas-collecting water guide plates Users who embed each other's settings. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein a conductor is provided at the center of the two negative anode electrode plates, and a conductive portion is provided at the lower end of the conductor. A conductive spacer is provided at the center, and the inside of the conductive spacer is provided with an internal thread for locking the conductor of the cathode electrode plate. Two sides of the base body are provided with two perforations for the two sides of the anode electrode plate. The conductive part penetrates out, and the center of the water inlet and outlet connector is provided with a hollow shaft post corresponding to the conductive partition pipe. The hollow shaft post is provided with an elastic element and a conductive post. The elastic force of the elastic element is used to make the upper end of the conductive post. It can be in close contact with the conductive part of the conductor. The lower end of the conductive post can be used to connect the negative wire. The top surface of the water inlet and outlet connector corresponds to the two conductive parts of the anode electrode plate. The lower end of the positive electrode conductive sheet can be connected to a positive electrode wire. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein the cathode and anode chambers of the two negative anode electrode plates are V-shaped. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein the cathode and anode chambers of the two negative anode electrode plates are porous, and the two gas-collecting water guide plates correspond to the cathode and anode chambers. There are partition ribs arranged in a radial pattern, whereby a plurality of cathode and anode water runners are formed between the plurality of partition ribs, respectively. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 2, wherein: the two gas collecting water guide plates are provided with two raw water inlet grooves corresponding to the water inlets of the two negative anode electrode plates, and the two gas collecting holes The periphery of the water guide plate is provided with a plurality of equally divided cathode and anode water outlets, and the periphery of the cathode and anode water outlet is provided with a plurality of equally divided anode and anode water outlet channels, so that raw water can The water inlet of the electrode plate flows into the two raw water inlet tanks of the two gas-collecting water guides, and then flows from the two raw water inlet tanks into the cathode and anode chambers of the two electrode plates in a radiating manner from the inside to the outside through the water inlet of the two negative anode electrode plates. Finally, those who flow out from the anode and anode water outlet channels respectively. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 14, wherein: the bottom surface of the gas collection water guide plate corresponding to the base body corresponds to a plurality of anode water outlets, and a circle is provided on the circumference of the circumference. Therefore, a gas-collecting and water-conducting chamber is formed on the bottom surface of the gas-collecting and water-conducting pan for oxygen molecular gas collection and anode water-conducting, so as to quickly store the oxygen and ozone generated by the anode electrode plate, and prevent the oxygen and ozone from mixing into the upper cathode Those in the water. The hydrogen molecule remelting device of the disc-shaped electrolytic cell according to claim 14, wherein: the top surface of the gas collecting water guide plate corresponding to the base body corresponds to a circle around the circumference of the plurality of anode water outlets Flange. Use the flange to raise the water level of the anode water, so that the ion membrane is sufficiently wet.