Hydrogen water generator with warning function and hydrogen generation system

The hydrogen water generator efficiently produces high-quality hydrogen water with minimal impurities and includes a warning system to ensure safety, addressing the limitations of existing generators by using a capillary tube and LED feedback.

JP7876605B2Active Publication Date: 2026-06-19林信涌

Patent Information

Authority / Receiving Office
JP · JP
Patent Type
Patents
Current Assignee / Owner
林信涌
Filing Date
2022-09-05
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing hydrogen water generators produce hydrogen water with impurities, require filtration, and lack a reliable warning system for potential gas leaks, posing safety risks and reducing effectiveness.

Method used

A hydrogen water generator with a simple structure that efficiently produces hydrogen water and humidified gas, featuring a capillary tube for bubble formation, a transparent cup for visual feedback, and a warning system using LED lights to indicate normal or abnormal operation, along with a hydrogen gas concentration detection device to prevent leaks.

Benefits of technology

Ensures high solubility of hydrogen in water without filtration, provides visual and audible warnings for safety, and prevents external gas leaks, making the system practical and safe for home use.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

In the hydrogen water generating device and hydrogen generating system with a warning function, the hydrogen water generating device includes a cup body for storing water, and an air supply structure, a handle, a thin tube, an exhaust structure, and a water flow structure provided on the cup body. The air supply structure receives hydrogen-containing gas from the outside of the cup body. The thin tube is located in the storage space of the cup body and is connected to the air supply structure. The exhaust structure is used to receive hydrogen-containing gas from the storage structure and send it to the outside of the cup body. The water flow structure is used to send water in the storage space to the outside of the cup body. The hydrogen-containing gas enters the water in the storage space through the air supply structure and the thin tube. This generates hydrogen water and humidified gas, which are respectively sent to the outside of the cup body through the water flow structure and the exhaust structure. When the system is operating normally, the cup body emits light of a first color, and when the system is not operating normally, the cup body emits light of a second color.
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Description

Technical Field

[0001] The present invention relates to a hydrogen water generator capable of generating hydrogen water and humidifying gas, and a hydrogen generation system thereof, and particularly to a hydrogen water generator capable of generating hydrogen water and humidifying gas and having a warning function, and a hydrogen generation system thereof.

Background Art

[0002] So far, mankind has highly valued life. The development of numerous medical technologies is all for combating diseases and prolonging human life. Also, most of the past medical methods were passive. That is, when a disease occurred, after diagnosing the cause, medical actions such as surgery, medication, chemotherapy or radiotherapy for cancer, or health care, rehabilitation, correction, etc. for chronic diseases were performed on the symptoms. However, in recent years, many medical experts have gradually studied preventive medical methods such as research on health foods, screening and early prevention of genetic diseases, and are trying to more actively prevent diseases that may occur in the future. In addition, numerous anti-aging and antioxidant technologies including coating-type care products and antioxidant foods / drugs are gradually being developed to extend human lifespan and are widely used by the general public.

[0003] Free radicals are molecules or ions with one or more unpaired electrons. They are highly reactive and tend to absorb electrons from nearby sources to maintain stability. Normal metabolism in the human body is a type of oxidation reaction, naturally generating free radicals. Furthermore, maintaining normal bodily functions requires the creation of numerous useful chemical substances and resistance to external pathogens. For example, enzyme production and phagocytosis of pathogens by white blood cells also generate free radicals. In addition to the internal factors mentioned above, the human body generates excess free radicals due to various external environmental influences, such as bad habits like smoking and alcoholism, radiation, ultraviolet rays and electromagnetic waves, and various forms of environmental pollution. Because free radicals have very strong oxidizing power, they attack and damage cells. Current research suggests that free radicals are a major cause of various chronic diseases, cancer, and aging.

[0004] The free radicals mentioned above can be expelled from the body as water through synthesis with inhaled hydrogen. This is because hydrogen is a powerful antioxidant with reducing properties. By reducing the number of free radicals in the human body with hydrogen, it is possible to restore an acidic body to a healthy alkaline state. This also leads to antioxidant, anti-aging, and even the elimination of chronic diseases, as well as beauty and healthcare effects. Furthermore, clinical trials have shown that in bedridden patients, inhaling hydrogen gas can alleviate the symptoms of lung damage caused by long-term high-concentration oxygen respiration. However, because the structure of the human trachea is not suitable for inhaling excessively dry gases, hydrogen gas cannot be inhaled by patients unless it is adequately humidified.

[0005] In addition to inhaling humidified hydrogen gas, the prevention or treatment of various diseases can also be achieved by medically drinking or injecting water rich in hydrogen (hydrogen gas water or hydrogen water). However, because hydrogen gas has low solubility in water, the human body cannot achieve a good therapeutic effect unless it drinks or is injected with a relatively large amount of hydrogen water. Therefore, efficiently producing humidified hydrogen gas and hydrogen water is an urgent goal to be achieved in this field.

[0006] Humidified hydrogen gas and hydrogen water can prevent disease or promote anti-aging by removing free radicals. They can be used in hospitals and medical facilities, and their use in home life can further enhance the early prevention of disease. Conventional home hydrogen water generators either electrolyze water or react magnesium with water to produce hydrogen. However, in the electrolysis method, minerals accumulate on the electrodes, affecting water quality, and in the magnesium reaction method, magnesium oxide remains in the water. Therefore, the quality of the hydrogen water produced cannot be guaranteed without a filtration process. However, the increased filtration process causes some of the hydrogen in the water to dissipate, reducing its effectiveness. Thus, there is a need to develop a hydrogen water generator for home use that is easy to use and does not produce excessive residues or minerals.

[0007] Furthermore, since the above-mentioned hydrogen water generator adds hydrogen-containing gas to the water, if a malfunction occurs in the device and the hydrogen-containing gas leaks to the outside, there is a risk of unforeseen consequences. Therefore, it is equally necessary to warn users of the above-mentioned abnormal situations to prevent accidents. [Overview of the project] [Problems that the invention aims to solve]

[0008] The object of the present invention is to provide a hydrogen water generator and hydrogen generation system that has a simple structure, is easy to operate, effectively generates hydrogen water and humidifying gas, has a warning function, provides a hydrogen water generator that does not produce excessive residue or minerals, and further provides an intuitive and effective warning function to make it more practical. [Means for solving the problem]

[0009] To achieve the above objectives, the present invention discloses a hydrogen water generator equipped with a warning function. The hydrogen water generator is characterized by comprising: a housing having an opening; a lid provided on the opening, the housing forming a storage space for containing water; a handle provided on the housing of the cup body for gripping by the user; an air supply structure provided on the cup body for receiving hydrogen-containing gas from outside the cup body; a thin tube provided in the storage space and communicating with the air supply structure for receiving the hydrogen-containing gas, the thin tube having a portion submerged in the water in the storage space and having a plurality of holes in its wall, so that the hydrogen-containing gas passes through these holes and is discharged from the thin tube into the storage space, and hydrogen water and humidifying gas are generated as the hydrogen-containing gas passes through these holes and enters the water in the storage space; an exhaust structure provided on the cup body for receiving the humidifying gas from the storage space and sending the humidifying gas to the outside of the cup body; and a water passage structure provided on the cup body for sending the hydrogen water in the storage space to the outside of the cup body.

[0010] The light-emitting member that emits light from outside the hydrogen water generator toward the hydrogen water generator, and whose emitted light passes through the cup body and is ejected from the cup body, is an LED that displays the first color when the hydrogen water generator is in a normal state and displays the second color when it is not in a normal state.

[0011] The cup body has a transparent outer wall. The light-emitting member is provided in the cup body and emits light toward the interior of the housing space, and the emitted light passes through the transparent outer wall and is emitted from the cup body.

[0012] The air supply structure, the exhaust structure, and the water passage structure are located in the cover.

[0013] Furthermore, it includes a water-permeable cover that removably covers the water-permeable structure, and the water-permeable cover includes a cover plate and an extension cord.

[0014] The capillary tube further includes a plurality of small filter cores, each corresponding to one of the holes, which filter the hydrogen-containing gas passing through the holes and cause a large number of fine bubbles to form as the hydrogen-containing gas passes through the holes and enters the water in the containment space.

[0015] Furthermore, the device includes a hydrogen gas concentration detection device that detects whether the hydrogen gas concentration outside the cup body is higher than a predetermined hydrogen concentration threshold. The cup body displays the first color if the hydrogen gas concentration detection device detects that the hydrogen gas concentration is lower than the predetermined hydrogen concentration threshold, and displays the second color if it detects that the hydrogen gas concentration is higher than the predetermined hydrogen concentration threshold.

[0016] Furthermore, a hydrogen generation system is disclosed. This hydrogen generation system is characterized by including a hydrogen generator that generates hydrogen-containing gas and a hydrogen water generator. The hydrogen water generator includes a housing having an opening, a lid provided in the opening, a cup body in which the housing forms a storage space for storing water, and a cup body that is removablely mounted on the hydrogen generator, a handle provided on the housing of the cup body for gripping by a user, an air supply structure provided on the cup body for receiving the hydrogen-containing gas from the hydrogen generator, a thin tube provided in the storage space and communicating with the air supply structure for receiving the hydrogen-containing gas, a portion of which is submerged in the water in the storage space, and the tube wall of the thin tube has a plurality of holes, so that the hydrogen-containing gas can pass through these holes and be discharged from the thin tube into the storage space, and hydrogen water and humidifying gas are generated when the hydrogen-containing gas passes through these holes and enters the water in the storage space, an exhaust structure provided on the cup body for receiving the humidifying gas from the storage space and sending the humidifying gas to the outside of the cup body, and a water passage structure provided on the cup body for sending the hydrogen water in the storage space to the outside of the cup body. Furthermore, the hydrogen generation system includes a hydrogen gas detection device that detects whether the hydrogen gas concentration exceeds a predetermined threshold for hydrogen gas concentration, and a warning device connected to the hydrogen gas detection device that issues a warning signal when the hydrogen gas detection device detects that the hydrogen gas concentration exceeds the predetermined threshold for hydrogen gas concentration.

[0017] The warning device is an LED light-emitting member provided in the hydrogen generator, which, when the hydrogen gas detection device detects that the hydrogen gas concentration does not exceed the predetermined threshold for hydrogen gas concentration, causes the cup body to display a first color, and when the hydrogen gas detection device detects that the hydrogen gas concentration exceeds the predetermined threshold for hydrogen gas concentration, emits the warning signal and causes the cup body to display a second color.

[0018] The warning device is an LED light-emitting member provided in the hydrogen water generator, which displays a first color when the hydrogen gas detection device detects that the hydrogen gas concentration does not exceed a predetermined threshold for hydrogen gas concentration, and emits a warning signal to display a second color on the cup when the hydrogen gas detection device detects that the hydrogen gas concentration exceeds a predetermined threshold for hydrogen gas concentration.

[0019] The hydrogen gas detection device is installed inside the hydrogen generator and detects whether the hydrogen gas concentration inside the hydrogen generator exceeds a predetermined threshold for hydrogen gas concentration. If the hydrogen gas detection device detects that the hydrogen gas concentration exceeds the predetermined threshold for hydrogen gas concentration, the warning device emits a warning signal to cause the cup body to display a second color.

[0020] The hydrogen gas detection device is located outside the hydrogen generator. The hydrogen gas detection device is connected to the hydrogen generator by wireless transmission and detects whether the hydrogen gas concentration around the hydrogen generator exceeds a predetermined threshold for hydrogen gas concentration. If the hydrogen gas detection device detects that the hydrogen gas concentration exceeds the predetermined threshold for hydrogen gas concentration, the warning device emits a warning signal to cause the cup body to display a second color.

[0021] Furthermore, it includes a plurality of associated hydrogen generators. Each associated hydrogen generator includes an associated cup body and an associated warning device. The associated warning device is provided on the housing of the associated hydrogen generator or on the associated cup body. The hydrogen gas detection device is connected to the plurality of associated hydrogen generators by wireless transmission, and when the hydrogen gas detection device detects that the hydrogen gas concentration around the hydrogen generator or the hydrogen gas concentration around the plurality of associated hydrogen generators exceeds a predetermined threshold for hydrogen gas concentration, the warning device and the associated warning device cause the cup body and the associated cup body to display a second color, respectively.

[0022] The warning device is a voice generating member that emits a warning sound as a warning signal when it is detected by the hydrogen gas detection device that the hydrogen gas concentration exceeds the threshold value of the predetermined hydrogen gas concentration.

[0023] The hydrogen generator further includes a capacitance type water level gauge that detects the level of water in the cup body of the hydrogen water generator when the cup body is installed in the hydrogen generator.

[0024] The hydrogen generator further includes a control module connected to the capacitance type water level gauge. The capacitance type water level gauge includes a high water level detector and a low water level detector. When the cup body is removed from the hydrogen generator and the high water level detector and the low water level detector cannot detect the high water level and the low water level in the cup body, the control module controls the hydrogen generator to stop generating the hydrogen-containing gas.

[0025] The hydrogen generator further includes a tank for storing water, an electrolytic cell provided in the tank for receiving the water in the tank and generating the hydrogen-containing gas by electrolyzing the water, an integrated flow path device vertically stacked on the tank and communicating with the tank for receiving the hydrogen-containing gas from the tank, a condensation filter device connected to the integrated flow path device for receiving and filtering the hydrogen-containing gas from the integrated flow path device, and a humidifying device vertically stacked on the tank and located between the tank and the integrated flow path Device and connected to the integrated flow path device for receiving and humidifying the filtered hydrogen-containing gas.

[0026] The condensation filter device has a condensation flow path. And the condensation filter device is removably inserted into the integrated flow path device for receiving the hydrogen-containing gas from the integrated flow path device and filtering the hydrogen-containing gas in the condensation flow path. <​The hydrogen generator further includes an atomizer. The atomizer is connected to the integrated flow path device and receives the humidified hydrogen-containing gas from the integrated flow path device, mixes the generated atomized gas with the hydrogen-containing gas to form a healthcare gas, and delivers it.

Advantages of the Invention

[0028] With the above structure, the present invention can achieve the following technical effects.

[0029] 1. Hydrogen water and humidified hydrogen-containing gas (or humidified gas) can be formed quickly and easily. In addition, the generated hydrogen water does not contain excessive minerals or magnesium oxide, so there is no need to perform a filtration procedure and it is possible to maintain a high solubility.

[0030] 2. By irradiating the fine bubbles in the cup body of the hydrogen water generator with the light-emitting member, a visual effect in appearance can also be generated, so it is possible to stimulate the consumer's purchasing desire and enable the user to grasp the operating status of the current system.

[0031] 3. In addition, not only can the water level in the hydrogen water generator be detected, but it is also possible to detect whether the hydrogen water generator is separated from the hydrogen generator and stop the generation of the hydrogen-containing gas, so the safety of the system and the user is further ensured.

[0032] 4. By detecting the presence or absence of external leakage of the hydrogen-containing gas and the situation where the environmental hydrogen concentration exceeds the standard, it is possible to alert the user or directly stop the device to avoid the occurrence of an accident.

[0033] water Regarding the advantages and spirit of the present invention of the elemental gas concentration detection device, it can be further understood from the following detailed description of the invention and the attached drawings.

Brief Description of the Drawings

[0034] [Figure 1]Figure 1 shows a schematic diagram of a hydrogen generation system based on a specific embodiment of the present invention. [Figure 2] Figure 2 shows a schematic diagram of the hydrogen generator and hydrogen water generator in the hydrogen generation system shown in Figure 1. [Figure 3] Figure 3 shows a schematic diagram of the internal structure of the hydrogen water generator shown in Figure 2. [Figure 4] Figure 4 shows the internal structure of a hydrogen water generator based on another specific embodiment of the present invention. [Figure 5] Figure 5 shows an exploded view of the tubular structure in Figure 3. [Figure 6] Figure 6 shows a schematic cross-sectional view of the tubular structure in Figure 5. [Figure 7] Figure 7 shows a schematic diagram of a hydrogen generation system based on another specific embodiment of the present invention. [Figure 8A] Figure 8A shows a schematic diagram of an external hydrogen gas detection assembly based on a specific embodiment of the present invention. [Figure 8B] Figure 8B shows a schematic diagram of an external hydrogen gas detection assembly based on another specific embodiment of the present invention. [Figure 9] Figure 9 shows a schematic diagram of the coordination between an external hydrogen gas detection assembly and multiple hydrogen generation systems based on another specific embodiment of the present invention. [Figure 10A] Figure 10A shows a schematic assembly diagram of the tank, electrolytic cell, and heat sink of a hydrogen generator based on a specific embodiment of the present invention. [Figure 10B] Figure 10B shows a cross-sectional view of the tank, electrolytic cell, and heat sink shown in Figure 10A. [Figure 10C] Figure 10C shows a cross-sectional view of the tank, electrolytic cell, and heat sink of a hydrogen generator based on another specific embodiment of the present invention. [Figure 11] Figure 11 shows a schematic diagram of the hydrogen generator tank, radiator, and fan from a different angle. [Figure 12] Figure 12 shows a simplified schematic exploded view of a hydrogen generator based on a specific embodiment of the present invention. [Figure 13] Figure 13 shows a simplified schematic diagram of the hydrogen generator from a different angle in Figure 12. [Figure 14] Figure 14 shows a simplified schematic exploded view of a hydrogen generator based on a specific embodiment of the present invention. [Modes for carrying out the invention]

[0035] Refer to Figures 1 and 2. Figure 1 shows a schematic diagram of a hydrogen generation system 1 based on a specific embodiment of the present invention. Figure 2 shows a schematic diagram of a hydrogen generator 10 and a hydrogen water generator 12 equipped with a warning function in the hydrogen generation system 1 of Figure 1. As shown in Figures 1 and 2, the hydrogen water generator 12 is detachably mounted on the hydrogen generator 10. The hydrogen generator 10 is capable of generating hydrogen-containing gas. In practical use, the hydrogen generator 10 may include components such as an electrolytic cell, a condenser filter, an integrated flow path, a humidifier, and an activated carbon filter rod to supply hydrogen-containing gas filtered by electrolysis of water. Alternatively, the hydrogen generator 10 may include a gas storage unit for storing hydrogen-containing gas, and the hydrogen-containing gas may be supplied directly from the gas storage unit.

[0036] Refer to Figures 2 and 3 together. Figure 3 shows a schematic diagram of the internal structure of the hydrogen water generator 12 shown in Figure 2. As shown in Figures 2 and 3, the hydrogen water generator 12 has a cup body 120, an air supply structure 122, a thin tube 124, an exhaust structure 126, and a water passage structure 128. The cup body 120 includes a housing 1201 and a lid 1202. The housing 1201 has an opening, and the lid 1202 is provided over the opening to cover it. The housing also forms a water-containing space 1200. The air supply structure 122, the exhaust structure 126, and the water passage structure 128 are provided on the lid 1202 of the cup body 120 and are used to connect the water-containing space 1200 with the outside of the cup body 120. The thin tube 124 is provided inside the water-containing space 1200 of the cup body 120. Furthermore, when water is contained in the containment space 1200, a portion of the thin tube 124 is submerged in water. In addition, one end of the thin tube 124 is connected to the air supply structure 122, and the other end, which is submerged in water, is equipped with multiple holes 1240.

[0037] When the hydrogen water generator 12 is connected to the hydrogen generator 10, the hydrogen-containing gas generated or supplied by the hydrogen generator 10 becomes receivable by the air supply structure 122. Subsequently, the hydrogen-containing gas enters the capillary tube 124, passes through the hole 1240 in the part of the capillary tube 124 that is submerged in water, and enters the water contained in the containment space 1200. The hydrogen-containing gas passes from inside the capillary tube 124 through the hole 1240. Capacity 1200 After entering the water, it increases the contact area between the hydrogen-containing gas and the water by forming tiny bubbles in the water.

[0038] After passing through the hole 1240 of the capillary tube 124, the hydrogen-containing gas forms a large number of fine bubbles, floats in the water, and moves upward. As the bubbles move upward, they become humidified by moisture. Furthermore, the form of a large number of fine bubbles significantly increases the contact area between the hydrogen-containing gas and water, thus further enhancing the degree of humidification. The humidified hydrogen-containing gas may also be called humidified gas. On the other hand, by forming a large number of fine bubbles, the hydrogen-containing gas can be effectively dispersed in water, and to improve the solubility of hydrogen in water, humidified gas and hydrogen water can be formed or generated simultaneously.

[0039] Refer again to Figures 2 and 3. In this specific embodiment, the water passage structure 128 of the hydrogen water generator 12 is located on the lid 1202 which is the ceiling of the cup body 120, and has a water passage lid 1280 that is removable and covers the water passage structure 128. Water flow lid body 1280 When the water passage structure 128 is removed or opened, the hydrogen water generated in the containment space 1200 can be sent out of the cup body 120 from the water passage structure 128. Alternatively, replenishment water from outside the cup body 120 can be introduced into the containment space 1200 of the cup body 120 from the water passage structure 128. In practice, the water passage cover 1280 includes a cover plate for covering the water passage structure 128 and an extension cord connected to the cover plate. This ensures that the cover plate remains connected to the cover 1202 by the extension cord even when it is opened from the water passage structure 128, thus eliminating the risk of it falling or being lost.

[0040] In addition, the exhaust structure 126 of the hydrogen water generator 12 in this specific embodiment is provided on the lid 1202, which is above the cup body 120. As described above, after passing through the hole 1240 of the capillary tube 124, the hydrogen-containing gas enters the water, forms fine bubbles, and rises, becoming humidified during the rising process. The humidified hydrogen-containing gas rises and collects above the containment space 1200, so it can be collected by the exhaust structure 126 and sent outside the cup body 120. This exhaust structure 126 may allow the patient to directly inhale the humidified hydrogen-containing gas (which may also be called humidified gas), or it may be connected to a portable or fixed atomizing / volatile gas generator to form a mixed gas with the humidified hydrogen-containing gas and the atomized gas (atomizing gas can be any of the group consisting of water vapor, atomizing chemicals, volatile essential oils, and combinations thereof) generated by the atomizing / volatile gas generator, and then allow the patient to inhale the mixed gas.

[0041] In practical use, the flow rate when the exhaust structure 126 delivers humidified hydrogen-containing gas can be within the range of 0.01 to 12 L / min, for example, between 1 and 6 L / min to match the human respiratory rate. In addition, to make it easy for the user to dispense hydrogen water, the hydrogen water generator 12 has a housing in the cup body 120. 1201 It may also include a handle 121 (shown in Figures 1 and 2) provided on the outer surface, which the user can grip to make it easier to pour hydrogen water.

[0042] Abnormal situations may occur during the operation of a hydrogen generation system. For example, after prolonged use, the hydrogen generator 10 or hydrogen water generator 12 may deteriorate and malfunction, or hydrogen gas may leak to the outside due to improper operation by the user. Since these abnormal situations may lead to accidents, it is necessary to have a mechanism that can warn the user and indicate whether the system is currently operating normally or not. In this invention, the user is alerted by a method in which the cup body 120 emits light of a different color depending on whether it is operating normally or abnormally. For example, when the hydrogen generator 10 or hydrogen water generator 12 is operating normally, the cup body 120 may emit blue or green light, but when the hydrogen generator 10 or hydrogen water generator 12 is not operating normally, the cup body 120 may emit yellow or red light. Therefore, the user can directly determine whether the system is operating normally or not from the color of the cup body 120. In addition, the hydrogen generator 10 or hydrogen water generator 12 may protect the entire system by directly performing specific actions depending on the system status.

[0043] For details, please refer again to Figure 2. As shown in Figure 2, a capacitive water level meter 100 and a light-emitting member 102 may be provided at the location where the hydrogen water generator 12 is installed in the hydrogen generator 10. The capacitive water level meter 100 can detect the water level in the cup body 120 of the hydrogen water generator 12 when the hydrogen water generator 12 is installed in the hydrogen generator 10. More specifically, the capacitive water level meter 100 includes two measuring units that can measure the high water level and the low water level in the cup body 120, respectively. This allows the user to know whether or not the water in the hydrogen water generator 12 should be refilled. Also, when the hydrogen water generator 12 is installed in the hydrogen generator 10, the hydrogen-containing gas generated in the hydrogen generator 10 enters the containment space 1200 of the cup body 120 through the air supply structure 122. However, if the hydrogen water generator 12 is removed from the hydrogen generator 10, there is a risk that the hydrogen-containing gas generated in the hydrogen generator 10 may leak to the outside, potentially causing an unexpected accident. The capacitive water level gauge 100 on the hydrogen generator 10 can be used to avoid the aforementioned external leakage accident of hydrogen-containing gas. In this specific embodiment, the hydrogen generator 10 may include a control module connected to the capacitive water level gauge 100. When the hydrogen water generator 12 is separated from the hydrogen generator 10, the two measuring units of the capacitive water level gauge 100 become unable to detect high or low water levels in the cup body 120, and therefore transmit a signal to the control module indicating that the water level cannot be detected. Alternatively, the control module actively verifies that the capacitive water level gauge 100 has not detected any water level. Subsequently, the control module controls the hydrogen generator 10 to stop generating hydrogen-containing gas. This prevents an accident in which hydrogen-containing gas from the hydrogen generator 10 leaks to the outside.

[0044] In the specific embodiment described above, the use of a water level gauge simultaneously achieves the functions of measuring the water level and detecting whether or not the hydrogen water generator 12 is connected to the hydrogen generator 10, thereby preventing external leakage of hydrogen-containing gas. However, in practical use, a contact detection unit may be separately provided at the location where the hydrogen water generator 12 is installed in the hydrogen generator 10, and the connection of the hydrogen water generator 12 to the hydrogen generator 10 may be determined by detecting whether or not the cup body 120 has come into contact with this contact detection unit.

[0045] The light-emitting member 102 on the hydrogen generator 10 emits a light ray toward the cup body 120 when the hydrogen water generator 12 is installed on the hydrogen generator 10. In this specific embodiment, since the outer wall of the cup body 120 can be made transparent, the light ray emitted from the light-emitting member 102 can pass through the cup body 120 and enter the containment space 1200. It should be noted that the position and number of light-emitting members 102 are not limited to those shown in Figure 2, and the design may be determined according to the needs of the user or designer. In practical use, the light-emitting member 102 may be a light-emitting diode (LED), but is not limited to this, and any member capable of emitting a light ray can be applied to the present invention.

[0046] The hydrogen-containing gas rises in the water of the containment space 1200 by forming fine bubbles. Therefore, the light rays emitted from the light-emitting member 102 enter the containment space 1200, are refracted or reflected by these fine bubbles, and then pass through the transparent outer wall to reach the outside. Because the cup body 120 has a transparent outer wall, the user can observe through the transparent outer wall that a large amount of fine bubbles of hydrogen-containing gas are generated on the wall of the tube 124 and floating upward. Furthermore, the light rays emitted from the light-emitting member 102 are irradiated by these fine bubbles, causing the light rays to be deflected or reflected, which affects the user. Cup size 120 By creating a sense of change in the internal light rays, it achieves a visually beautiful effect.

[0047] In addition, the light-emitting member 102 may have different light-emitting modes. In practical use, the light-emitting member 102 can perform these light-emitting modes under the control of the aforementioned control module. In different light-emitting modes, the light-emitting member 102 can emit light of different colors or exhibit different flashing patterns. For example, hydrogen Contains If the flow rate of gas entering the cup body 120 is large, the light-emitting member 102 may emit light with a high flashing frequency. Also, when the hydrogen generator 10 and the hydrogen water generator 12 are operating normally (for example, when the hydrogen-containing gas supply rate is within the normal range, or when the capacitive water level gauge 100 is operating normally, etc.), the light-emitting member 102 may emit light having a first color, such as blue light or green light, to indicate to the user that the current system is operating normally. However, when the hydrogen generator 10 and the hydrogen water generator 12 are not operating normally (for example, when the hydrogen-containing gas supply rate is outside the normal range, or when there is no supply of hydrogen-containing gas, or when the capacitive water level gauge 100 is malfunctioning, etc.), the light-emitting member 102 may emit light having a second color, such as yellow light or red light, to indicate to the user that the current system is not operating normally or is malfunctioning. As a result, the light-emitting element 102 can not only produce different visual effects, but also reliably guarantee the safety of the system device and the user by presenting the current system status to the user.

[0048] The above-mentioned light-emitting member may be provided inside the hydrogen water generator. Now, refer to Figure 4. Figure 4 shows an internal structure diagram of a hydrogen water generator 12 based on another specific embodiment of the present invention. As shown in Figure 4, the hydrogen water generator 12 further includes a light-emitting member 130 provided on the lid 1202 of the cup body 120 and capable of emitting a ray of light into the containment space 1200. As a result, the ray of light is refracted or reflected by fine bubbles and then passes through the transparent outer wall of the cup body 120 to reach the outside. This light-emitting member 130 may be controlled by a control unit (not shown) of the hydrogen water generator 12, or by a device connected to the hydrogen water generator 12 (for example, a hydrogen generator 10). The number and installation location of the light-emitting members 130 can be determined according to the needs of the user or designer. The light-emitting member 130, like the light-emitting member 102 in the specific embodiment described above, can not only produce different visual effects, but can also ensure the safety of the system device and the user by presenting the current system status to the user through different emission modes. It should be noted that the other units of the hydrogen water generator 12 in this specific embodiment are almost identical in structure and function to the corresponding units in the specific embodiments described above, and therefore will not be described in detail again here.

[0049] In the specific embodiment described above, the capillary tube 124 can be used to deliver hydrogen-containing gas into the water of the containment space 1200 to form a large number of fine bubbles. The structure and function of the capillary tube 124 will be described in detail below. Refer to Figures 5 and 6. Figure 5 shows an exploded view of the structure of the capillary tube 124 in Figure 3, and Figure 6 shows a schematic cross-sectional view of the capillary tube 124 in Figure 5. As shown in Figures 5 and 6, the capillary tube 124 includes an air supply column 1242 and an air supply base 1244. The air supply column 1242 is connected to the air supply structure 122 on one side and has a first air supply channel 1243. The position of the air supply base 1244 can be submerged in the water of the containment space 1200. Furthermore, the air supply base 1244 includes an air supply base body 1245 and an air supply lid 1246. The air supply base 1245 is connected to the air supply column 1242 and has a second air supply channel 1247 and a plurality of air supply holes 1248. The second air supply channel 1247 is connected to the first air supply channel 1243, and the air supply holes 1248 are connected to the second air supply channel 1247. The air supply cover 1246 is fitted onto the air supply base 1245 and has a plurality of holes 1240 corresponding to each of the air supply holes 1248. Thus, the holes 1240 are each connected to the second air supply channel 1247 via the air supply holes 1248. When hydrogen-containing gas enters the capillary tube 124 from the air supply structure 122, the hydrogen-containing gas passes through the first air supply channel 1243, the second air supply channel 1247, and the air supply holes 1248 in that order. Finally, the bubbles form by entering the water in the containment space 1200 via the hole 1240.

[0050] In practical use, the size of the hole 1240 can be designed according to the needs of the user or designer, and the size of the bubbles formed will vary depending on the hole 1240. However, in this specific embodiment, a small filter core 1249 may be provided between the hole 1240 and the injection hole 1248 to filter the hydrogen-containing gas passing through the hole 1240, in order to ensure that there are no concerns regarding the quality and safety of the hydrogen-containing gas injected into the water. This small filter core 1249 can also increase the contact area with water by dividing the hydrogen-containing gas into fine bubbles, thereby improving the dissolved concentration of the hydrogen-containing gas in the water. Therefore, the size of the bubbles formed in this specific embodiment can be controlled by the small filter core 1249, not by the hole 1240. In actual application, the small filter core 1249 may be an activated carbon filter core, a drinking water filter core, etc., but is not limited to these. In addition, the tubular tube 124 further includes a fixing member 1250 having a plurality of fixing holes 1251 for housing and fixing the small filter core 1249. Furthermore, the air supply base body 1245 has a groove 1252 on the surface facing the air supply cover body 1246 for accommodating the fixing member 1250.

[0051] As shown in Figure 5, the hole 1240 has a hollow frustoconical structure in which the opening facing the containment space 1200 is larger than the area of ​​the opening facing the air injection hole 1248. This improves the degree of dispersion when hydrogen-containing gas, which is in the form of fine bubbles, is injected into the water. Conversely, if the opening facing the containment space 1200 is smaller than the area of ​​the opening facing the air injection hole 1248, the hydrogen-containing gas in the form of fine bubbles will aggregate to form larger bubbles, thus reducing the contact area of ​​the hydrogen-containing gas in the drinking water.

[0052] To improve the efficiency of delivering hydrogen-containing gas in a fine bubble state by enabling the average distribution of the amount of hydrogen-containing gas flowing out from each hole 1240, and to ensure a uniform amount of dissolved hydrogen in the water within the containment space 1200, the second injection channel 1247 gradually widens from the connection point with the first injection channel 1243 toward both ends of the injection base body 1245. Therefore, the second injection channel 1247 has a channel design that is narrow in the center and wide at both ends, making it possible to increase the flow rate of hydrogen-containing gas from the connection point toward both ends. This prevents a situation where not all of the holes 1240 are fully utilized, and most of the hydrogen-containing gas is injected into the water from near the connection point with the first injection channel 1243.

[0053] As described in the above-mentioned specific embodiment, the light-emitting member 102 installed in the hydrogen generator 10 or the light-emitting member 130 in the hydrogen water generator 12 has multiple light-emitting modes and emits light of different colors, thereby indicating to the user whether the current system is operating normally, for example, whether there is an external leak of hydrogen-containing gas. In response to the above-mentioned abnormal situation, the hydrogen generation system of the present invention may include a device for detecting the hydrogen gas concentration outside the hydrogen generator. Now, refer to Figure 7. Figure 7 shows a schematic diagram of a hydrogen generation system 1 based on another specific embodiment of the present invention. As shown in Figure 7, the difference between this specific embodiment and the specific embodiment described above is that the hydrogen generator 10 of the hydrogen generation system 1 in this specific embodiment further includes a hydrogen gas concentration detection device 104 capable of detecting the hydrogen gas concentration outside the hydrogen generator 10. It should be noted that the other units of the hydrogen generation system 1 in this specific embodiment have the same or similar structure and function as the corresponding units in the specific embodiment described above, and therefore will not be described in detail again here. Therefore, in the present invention, the hydrogen generation system includes a hydrogen generator, a hydrogen water generator (including a cup body, handle, air supply structure, thin tube, exhaust structure and water passage structure, etc.), and hydrogen gas to warn the user of whether or not hydrogen gas is leaking outside the system. concentrationThe system may include detection devices and warning devices. In a specific embodiment, the warning device may be a light-emitting member 102 provided in the hydrogen generator 10, which generates a warning signal (second-color light) by emitting light onto the cup body 120 of the hydrogen water generator 12 having a transparent outer wall. Alternatively, in another specific embodiment, the warning device may be a light-emitting member 130 provided in the cup body 120, which generates a warning signal (second-color light) by emitting light onto the cup body 120 having a transparent outer wall. Furthermore, the warning device may also be a sound-generating member provided in the hydrogen generator or hydrogen water generator, which may generate a warning sound as a warning signal to indicate a system malfunction to the user when the aforementioned abnormal situation occurs.

[0054] In the specific embodiment shown in Figure 7, the control unit of the hydrogen generator 10 can compare the external hydrogen concentration detected by the hydrogen gas concentration detection device 104 with a predetermined hydrogen concentration threshold. If the comparison reveals that the hydrogen concentration outside the hydrogen generation system 1 is higher than the predetermined hydrogen concentration threshold, the control unit can determine that hydrogen-containing gas is leaking to the outside. Subsequently, the control unit controls the light-emitting element 102 on the hydrogen generator 10 or the light-emitting element 130 in the hydrogen water generator 12 to emit the aforementioned second color light, such as yellow light or red light, to indicate to the user that the current system is not functioning normally or is malfunctioning. Conversely, if the comparison reveals that the hydrogen concentration outside the hydrogen generation system 1 is lower than the predetermined hydrogen concentration threshold, the control unit controls the light-emitting element 102 on the hydrogen generator 10 or the light-emitting element 130 in the hydrogen water generator 12 to emit the aforementioned first color light, such as blue light or green light, to indicate to the user that the current system is currently operating normally. It should be noted that, in practical use, the fact that a comparison shows the hydrogen concentration outside the hydrogen generation system 1 is lower than a predetermined hydrogen concentration threshold does not necessarily mean that the system is operating normally. The hydrogen generation system 1 may be experiencing abnormal conditions or malfunctions other than external hydrogen gas leakage. If the control unit detects any of these abnormal or malfunctioning conditions, it will control the light-emitting element 102 or 130 to emit a second color of light to warn the user that the system is currently malfunctioning or has malfunctioned.

[0055] If the control unit determines from the external hydrogen gas concentration detected by the hydrogen gas concentration detection device 104 that there is an external leak of hydrogen-containing gas into the hydrogen generation system 1, it may not only change the light emission mode of the light-emitting member 102 or 130, but also directly stop the generation of hydrogen gas by the hydrogen generator 10 to avoid the occurrence of an unexpected situation.

[0056] To directly control the light-emitting member 102 or light-emitting member 130 to emit a second color of light, the hydrogen gas concentration detection device described above can be installed in the hydrogen generator, or it may be installed on, for example, the cup body 120 on the hydrogen water generator 12. The hydrogen gas concentration detection device installed in the hydrogen water generator 12 may be electrically connected to the control unit of the hydrogen generator 10 when the hydrogen water generator 12 is installed in the hydrogen generator 10, and transmits the detection result to the control unit. The control unit then controls the light emission mode of the light-emitting member or stops the generation of hydrogen-containing gas by the hydrogen generator 10 based on the detection result.

[0057] Furthermore, the hydrogen gas concentration detection device may be provided in addition to the hydrogen generator and the hydrogen water generator. Refer to Figures 8A and 8B. Figure 8A shows a schematic diagram of an external hydrogen gas detection assembly 14 based on a specific embodiment of the present invention, and Figure 8B shows a schematic diagram of an external hydrogen gas detection assembly 14' based on another specific embodiment of the present invention. As shown in Figure 8A, the external hydrogen gas detection assembly 14 may have a plug (not shown) and is directly inserted into the power socket S adjacent to the power plug 16 of the hydrogen generator 10. Also, as shown in Figure 8B, the external hydrogen gas detection assembly 14' has a plug and a socket 143' and can be directly inserted into the power socket S. Furthermore, the power plug 16 of the hydrogen generator 10 is inserted into the socket 143 of the external hydrogen gas detection assembly 14'. In the specific embodiments described above, the external hydrogen gas detection assembly 14 may be part of the hydrogen generation system 1. In the embodiment shown in Figure 8A, the external hydrogen gas detection assembly 14 exchanges signals with the hydrogen generator 10 and transmits the detected hydrogen gas concentration in the external environment to the control unit of the hydrogen generator 10 for comparison, thereby enabling it to determine whether the hydrogen gas concentration outside the hydrogen generation system 1 exceeds a standard. Alternatively, the external hydrogen gas detection assembly 14 can directly determine whether the hydrogen gas concentration outside the hydrogen generation system 1 exceeds a standard and notifies the control unit of the hydrogen generator 10 to change the emission mode of the light-emitting element and stop hydrogen generation. Furthermore, in the embodiment shown in Figure 8B, in addition to the functions described above, if the external hydrogen gas detection assembly 14' detects that the hydrogen gas concentration outside the hydrogen generation system 1 exceeds a standard, it can also directly stop the hydrogen generator 10 by directly stopping the power supply from the power socket S without going through the control unit of the hydrogen generator 10.

[0058] Refer to Figure 9. Figure 9 shows a schematic diagram of the cooperation between an external hydrogen gas detection assembly 14 and a plurality of hydrogen generation systems 1 based on another specific embodiment of the present invention. As shown in Figure 9, the external hydrogen gas detection assembly 14 may exchange signals simultaneously with the control units of the hydrogen generators 10 in the plurality of hydrogen generation systems 1. It should be noted that although Figure 9 shows the case in which the external hydrogen gas detection assembly 14 cooperates with four hydrogen generation systems 1, in practice, the number of hydrogen generation systems 1 is not limited to four. In this specific embodiment, these hydrogen generation systems 1 and the external hydrogen gas detection assembly 14 are located in the same area. Therefore, the external hydrogen gas detection assembly 14 can detect the hydrogen gas concentration in the external environment of these hydrogen generation systems 1. When an excess of the hydrogen gas concentration standard is detected, the light-emitting member of each hydrogen generation system 1 changes its light-emitting mode, and hydrogen generation is stopped. Ultimately, the direct shutdown of each hydrogen generation system 1 ensures the safety of each hydrogen generation system 1 and its users.

[0059] Next, the internal structure of the hydrogen generator in the specific embodiment described above will be further explained. Refer to Figures 10A and 10B. Figure 10A shows a schematic assembly diagram of the tank 51, electrolytic cell 52, and heat sink 53 of the hydrogen generator 5 based on a specific embodiment of the present invention. Figure 10B shows a schematic assembly diagram of Figure 10 AThese are cross-sectional views of the tank 51, electrolytic cell 52, and radiator 53. As shown in Figures 10A and 10B, in this specific embodiment, the electrolytic cell 52 is located inside the tank 51 and generates hydrogen-containing gas by receiving water in the tank 51 and performing electrolysis. The water supply pipe 531, discharge pipe 532, and pipe structure 533 of the radiator 53 all have a flattened pipe structure. Furthermore, in order to connect the internal space of the tank 51 with the inside of the water supply pipe 531, discharge pipe 532, and pipe structure 533 of the radiator 53, the shapes of the first opening 514 and the second opening 515 of the tank 51 correspond to the shapes of the water supply pipe 531 and the discharge pipe 532, respectively. In practice, as shown in Figure 10A, the width of the water supply pipe 531, discharge pipe 532, and pipe structure 533 may be equal to the length of the side of the tank 51. In other words, the first opening 514 and the second opening 515 of the tank 51 have a large area and coverage range. Therefore, when the hydrogen generator is in operation, the electrolyzed water containing thermal energy flows rapidly and in large quantities to the radiator 53 through the first opening 514 of the tank 51, and then passes through the pipe structure 533 to dissipate heat. Furthermore, the electrolyzed water after heat dissipation can also rapidly return to the tank 51 through the second opening 515 of the tank 51, thus improving the heat dissipation rate. However, the width of the water supply pipe 531, the water discharge pipe 532, and the pipe structure 533 of the radiator 53 is not limited to this; the width may be any length or may be determined as needed. Moreover, in this specific embodiment, in order to extend the time that the electrolyzed water containing thermal energy remains in the pipe structure 533 and improve the heat dissipation efficiency, the pipe structure 533 has a corrugated delay structure 5331. In practical use, the shape and installation method of the delay structure 5331 are not limited to this, and may be the shape and installation method of the specific embodiment described above.

[0060] The heat sink in the hydrogen generator in the present invention may be located not only on the right side of the tank (see Figure 10A) but also on the left side of the tank. Furthermore, the number and installation position of the heat sinks in the hydrogen generator in the present invention are not limited to these. Now, refer to Figure 10C. Figure 10C shows a cross-sectional view of the tank 51, electrolytic cell 52, and heat sink 53 of a hydrogen generator 5 based on another specific embodiment of the present invention. In this specific embodiment, the hydrogen generator 5 may simultaneously include two sets of heat sinks 53 provided on both the left and right sides of the tank 51. The functions of the tank 51, electrolytic cell 52, and heat sink 53 in this specific embodiment are substantially the same as the functions of the corresponding components in the specific embodiment described above, and therefore will not be described in detail again here. In addition, in order to improve the heat dissipation rate, the hydrogen generator may further include a plurality of heat dissipation fins provided on the outside of the pipe structure.

[0061] Refer to Figures 10A, 10B, and 11. Figure 11 shows a schematic structural view from a different angle of the tank 51, radiator 53, and fan 55 of the hydrogen generator 5 in a specific embodiment of Figure 10A. As shown in Figures 10A, 10B, and 11, after the radiator 53 is connected to the tank 51, the water supply pipe 531, water discharge pipe 532, pipe structure 533 of the radiator 53, and the side wall of the tank 51 form a heat dissipation air passage 54. The hydrogen generator 5 may further include a fan 55 corresponding to the heat dissipation air passage 54 in order to introduce air from the external environment into the heat dissipation air passage 54. In practice, when the radiator 53 dissipates heat, all the thermal energy generated in the electrolyzed water after electrolysis is transferred to the pipe structure 533 of the radiator 53. At this time, the fan 55 can reduce the thermal energy and temperature of the pipe structure 533 by introducing outside air into the heat dissipation air passage 54. It should be noted that the number and placement of fans in the hydrogen generator in this invention are not limited to those described herein. In a specific embodiment, the fans may include a first fan and a second fan, each provided at both ends of the heat dissipation air passage. The first fan can introduce air from the external environment into the heat dissipation air passage, and the second fan can lead the air from the heat dissipation air passage out to the external environment. In another specific embodiment, if the hydrogen generator simultaneously includes two sets of heat radiators, each provided on the left and right sides of the tank, the hydrogen generator may also include two sets of fans, each provided on the left and right sides of the tank and corresponding to the heat dissipation air passage formed by the heat radiators.

[0062] Refer to Figures 12 and 13. Figure 12 shows a simplified schematic exploded view of a hydrogen generator 6 based on a specific embodiment of the present invention. Figure 13 shows a simplified schematic view of the hydrogen generator 6 from a different angle as shown in Figure 12. As shown in Figures 12 and 13, the hydrogen generator 6 in this specific embodiment includes an electrolytic cell (not shown), a tank 602, a humidifier 603, an integrated flow channel device 604, a condensation filter device 605, a hydrogen water cup 606, and an atomizer 607. The humidifier 603 is stacked vertically on the tank 602, and the integrated flow channel device 604 is stacked vertically on the humidifier 603. The condensation filter device 605 is located in the housing space within the integrated flow channel device 604.

[0063] The condensing filter device 605 can be used to filter hydrogen-containing gas and may have a condensing channel 6051. In practical application, the condensing filter device 605 can be fitted into the integrated channel device 604 and can be easily replaced by removing it from the side of the integrated channel device 604. Therefore, it is not necessary to disassemble the entire hydrogen generator 6 for replacement. However, the condensing filter device 605 may also be fixedly installed within the integrated channel device 604. The humidifier 603 includes a humidifying chamber (not shown) and a communication chamber 6031. The humidifying chamber contains replenishment water and can be used to humidify hydrogen-containing gas. The communication chamber 6031 connects the tank 602 and the integrated channel device 604 By connecting these, the hydrogen-containing gas generated in the electrolytic cell provided in the tank 602 can be used to enter the condensation channel 6051 of the condensation filter device 605. The hydrogen water cup 606 can be used to hold drinking water. Furthermore, the hydrogen water cup 606 is used to inject hydrogen-containing gas into drinking water to form hydrogen-containing water. The integrated flow channel device 604 includes an air supply channel 6041, an exhaust channel 6042, and a gas communication channel 6043. The air supply channel 6041 and the exhaust channel 6042 can be selectively connected to the hydrogen water cup 606, and the gas communication channel 6043 can be selectively connected to the air supply channel 6041 and the exhaust channel 6042. The atomizer 607 is connected to the exhaust channel 6042 of the integrated flow channel device 604 to receive the hydrogen-containing gas, and can also generate a separate atomizing gas and mix it with the hydrogen-containing gas to form a healthcare gas. In addition, the humidifier 603, condensing filter device 605, atomizer 607, and hydrogen water cup 606 may be fitted into or directly connected to the integrated flow path device 604.

[0064] Therefore, once the hydrogen-containing gas generated in the electrolytic cell leaves the water surface in tank 602, it quickly enters the communication chamber 6031 of the humidifier 603. Subsequently, the hydrogen-containing gas passes through the communication chamber 6031 of the humidifier 603, the condensation flow path 6051 of the condensation filter device 605, the air supply flow path 6041 of the integrated flow path device 604, the exhaust flow path 6042, and the atomizer 607 in that order. The hydrogen-containing gas may also selectively pass through the hydrogen water cup 606. However, it should be understood that the above flow direction of the hydrogen-containing gas is one embodiment of the hydrogen generator having a heat sink in the present invention, and those skilled in the art may, as necessary, spontaneously adjust the order of each component, and are not limited to the above.

[0065] The atomizer 607 can form a healthcare gas by generating an atomized gas and mixing it with a hydrogen-containing gas. The atomized gas can be selected from one of the group consisting of water vapor, atomizing agent, and volatile essential oil, or a combination thereof. In a specific embodiment, the atomizer 607 includes an oscillator. The oscillator generates an atomized gas by atomizing the water, atomizing agent, or volatile essential oil added to the atomizer 607 through vibration. Hydrogen-containing A healthcare gas is formed by mixing gas and atomizing gas. The atomizer 607 can be selectively turned on or off according to the user's needs to supply the healthcare gas mixed with the atomizing gas for the user to inhale, or the mixed gas (i.e.) ,acid It is possible to supply only hydrogen-containing gas (diluted with a primary gas) and have the user inhale it.

[0066] As mentioned above tank In addition to the installation method of the specific embodiment described above, other configurations may also be used. As shown in Figure 12, in the specific embodiment, the water pump 608 is provided at the bottom of the tank 602 and can be connected to the lower cavity of the tank 602. In practical use, the water pump 608 is powered by its impeller, which is connected to the tank 602By introducing the electrolyzed water located in the lower cavity into the electrolytic cell, the electrolysis efficiency can be improved. Furthermore, the water pump 608 accelerates the electrolyzed water located in the lower cavity and causes it to flow into the upper cavity. As a result, the electrolyzed water located in the upper cavity is also accelerated and flows from the first opening to the heat sink, where it dissipates heat. This improves the heat dissipation efficiency.

[0067] In other words, the hydrogen generator in the present invention isolates electrolyzed water containing thermal energy in the upper cavity of the tank by a partition, and effectively dissipates heat using a heat sink connecting the upper and lower cavities. Furthermore, the hydrogen generator in the present invention can improve heat dissipation efficiency by reducing the thermal energy of the heat sink using a heat sink and fan provided in the heat dissipation air passage. In addition, the hydrogen generator in the present invention can also improve heat dissipation efficiency by actively introducing electrolyzed water in the tank into the heat sink using a water pump and dissipating heat. Moreover, the hydrogen generator can improve heat dissipation efficiency by providing a structure that extends the length of the path within the pipe structure of the heat sink.

[0068] Furthermore, the hydrogen generator in the present invention may be configured in ways other than the arrangement described above. Now, refer to Figure 14. Figure 14 shows a simplified schematic exploded view of a hydrogen generator 7 based on a specific embodiment of the present invention. As shown in Figure 14, the difference between this specific embodiment and the specific embodiment described above is that the hydrogen generator 7 of this specific embodiment includes only a tank 702, an integrated flow path device 704, a condensation filter device 705, and an atomizer 707. The integrated flow path device 704 is the tank 702 Stacked vertically on top of, condensation filter device 705 is an integrated flow channel device 704 It is installed inside. The atomizer 707 is also connected to the integrated flow channel device 604. The hydrogen-containing gas generated in the electrolytic cell of tank 702 quickly enters the communication chamber 7021 once it leaves the water surface of tank 702. Subsequently, the hydrogen-containing gas passes through the communication chamber 7021, the condensation channel of the condensation filter device 705, the supply channel of the integrated flow channel device 704, the exhaust channel, and the atomizer 707 in that order.

[0069] Furthermore, the hydrogen generator 7 of the present invention also includes a water supply port 708 provided in the integrated flow channel device 704 and communicating with the flow channel of the integrated flow channel device 704. In practical use, the water supply port 708 can communicate with the exhaust flow channel of the integrated flow channel device 704. As the hydrogen generator 7 reacts for a long period of time, the amount of water in the tank 702 gradually decreases. Therefore, the user can replenish the amount of water in the tank 702 by adding water from the water supply port 708. When the user adds water from the water supply port 708, the water passes through the condensation flow channel and communication chamber 7021 of the condensation filter device 705 to reach the tank 702. Furthermore, when the condensation filter device 705 operates, it filters the electrolyte in the electrolyzed water, leaving the electrolyte in the condensation flow channel. Therefore, when the user adds water from the water supply port 708 and the water passes through the condensation flow channel, the electrolyte remaining in the condensation flow channel can also return to the tank 702 along with the water. It should be noted that the installation location of the water inlet 708 is not limited to this. In a specific embodiment, the water inlet may be connected to the atomizer. In another specific embodiment, the water inlet may be directly connected to the condensation flow path of the condensation filter device.

[0070] As described above, the hydrogen water generator and hydrogen generation system of the present invention can easily produce hydrogen water and humidified hydrogen-containing gas (or humidified gas). Furthermore, since the generated hydrogen water does not contain excess minerals or magnesium oxide, there is no need to perform a filtration procedure, and it is possible to maintain high solubility. In addition, by illuminating the fine bubbles inside the cup of the hydrogen water generator with a light-emitting element, a visual effect can be created, which can stimulate consumer purchasing intent and allow the user to understand the current operating status of the system. Moreover, the capacitive water level meter on the hydrogen generator can not only detect the water level inside the hydrogen water generator, but can also detect whether the hydrogen water generator has separated from the hydrogen generator and stop the generation of hydrogen-containing gas, thereby further ensuring the safety of the system and the user. The hydrogen generation system further includes a hydrogen gas concentration detection device on or outside the device that can detect whether or not there is an external leakage of hydrogen-containing gas or whether the environmental hydrogen concentration exceeds the standard, thereby alerting the user or directly stopping the device to avoid accidents.

[0071] The detailed descriptions of the preferred specific embodiments described above are intended to more clearly represent the features and spirit of the invention and do not limit the scope of the invention by the preferred specific embodiments disclosed above. Rather, the detailed descriptions above are intended to cover a variety of modifications and to be constructed with equivalence within the scope of the rights claimed by the invention. Accordingly, the scope of the rights claimed by the invention should be interpreted most broadly based on the above description so as to cover all possible modifications and equivalent configurations.

Claims

1. A hydrogen water generator equipped with a warning function, A housing having an opening, a cup body including a lid provided in the opening, the housing forming a storage space for holding water, A handle provided on the housing of the cup body for gripping by the user, An air supply structure provided in the cup body for receiving hydrogen-containing gas from outside the cup body, A tubular tube provided within the aforementioned containment space and in communication with the air supply structure to receive the hydrogen-containing gas, wherein a portion of the tubular tube is submerged in the water of the containment space, and the tube wall of the tubular tube has a plurality of holes, so that the hydrogen-containing gas passes through these holes and is discharged from the tubular tube into the containment space, and hydrogen water and humidifying gas are generated as the hydrogen-containing gas passes through these holes and enters the water of the containment space, An exhaust structure is provided in the cup body to receive the humidifying gas from the containment space and to send the humidifying gas to the outside of the cup body, The cup body includes a water passage structure that sends the hydrogen water in the containment space to the outside of the cup body, A hydrogen water generator characterized in that a light-emitting member, which emits light from outside the hydrogen water generator toward the hydrogen water generator and whose emitted light passes through the cup body and is emitted from the cup body, emits a first color when the hydrogen water generator is in a normal state and emits a second color when the hydrogen water generator is not in a normal state, thereby informing the user that the hydrogen water generator is in an abnormal state.

2. The hydrogen water generator according to claim 1, characterized in that the cup body has a transparent outer wall, the light-emitting member is provided in the cup body and emits light toward the interior of the containment space, and the emitted light passes through the transparent outer wall and is ejected from the cup body.

3. The hydrogen water generator according to claim 1, characterized in that the air supply structure, the exhaust structure, and the water passage structure are located in the lid.

4. Furthermore, the hydrogen water generator according to claim 1 is characterized in that it includes a water-conducting cover that is removable and covers the water-conducting structure, and the water-conducting cover includes a cover plate and an extension cord.

5. The hydrogen water generator according to claim 1, further comprising a plurality of small filter cores corresponding to each of the holes, which filter the hydrogen-containing gas passing through the holes and cause a large number of fine bubbles to form when the hydrogen-containing gas passes through the holes and enters the water in the containment space.

6. Furthermore, the hydrogen water generator according to claim 1 includes a hydrogen gas concentration detection device that detects whether the hydrogen gas concentration outside the cup body is higher than a predetermined hydrogen concentration threshold, wherein the cup body displays the first color when the hydrogen gas concentration detection device detects that the hydrogen gas concentration is lower than the predetermined hydrogen concentration threshold, and displays the second color when it detects that the hydrogen gas concentration is higher than the predetermined hydrogen concentration threshold.

7. A hydrogen generator that produces hydrogen-containing gas, Display device including housing, A hydrogen gas detection device that detects whether or not the hydrogen gas concentration exceeds a predetermined threshold for hydrogen gas concentration, Includes a warning device connected to the hydrogen gas detection device, which issues a warning signal when the hydrogen gas detection device detects that the hydrogen gas concentration exceeds a predetermined threshold for hydrogen gas concentration, The warning device is a light-emitting member, and when the hydrogen gas detection device detects that the hydrogen gas concentration does not exceed the predetermined threshold for hydrogen gas concentration, the light-emitting member displays a first color on the housing, and when the hydrogen gas detection device detects that the hydrogen gas concentration exceeds the predetermined threshold for hydrogen gas concentration, the light-emitting member displays a second color on the housing. A hydrogen generation system characterized by the following features.

8. The hydrogen generation system according to claim 7, characterized in that the warning device is an LED light-emitting member.

9. The presenting device is a hydrogen water generator having a housing, The housing forms a storage space for storing water, and the housing is detachably attached to the hydrogen water generator. The hydrogen water generating device further, A handle provided on the housing for the user to grasp, An intake structure provided in the housing for receiving the hydrogen-containing gas from the hydrogen water generator, A capillary tube provided in the aforementioned containment space and in communication with the intake structure to receive the hydrogen-containing gas, wherein a portion of the capillary tube is submerged in the water in the containment space, and the wall of the capillary tube has a plurality of holes, so that the hydrogen-containing gas can pass through these holes and be discharged from the capillary tube into the containment space, and hydrogen water and humidifying gas are generated when the hydrogen-containing gas passes through these holes and enters the water in the containment space, An exhaust structure provided in the housing receives the humidifying gas from the containment space and sends the humidifying gas to the outside of the housing, A water passage structure provided in the housing for sending the hydrogen water in the containment space to the outside of the housing, The hydrogen generation system according to claim 7, characterized by including the following:

10. The hydrogen gas detection device is provided inside the hydrogen generator and detects whether the hydrogen gas concentration inside the hydrogen generator exceeds a predetermined threshold for hydrogen gas concentration, and if the hydrogen gas detection device detects that the hydrogen gas concentration exceeds the predetermined threshold for hydrogen gas concentration, the warning device emits a warning signal to cause the housing to display a second color, as described in claim 7.

11. The hydrogen gas detection device is provided outside the hydrogen generator, and the hydrogen gas detection device is connected to the hydrogen generator by wireless transmission to detect whether the hydrogen gas concentration around the hydrogen generator exceeds a predetermined threshold for hydrogen gas concentration, and if the hydrogen gas detection device detects that the hydrogen gas concentration exceeds the predetermined threshold for hydrogen gas concentration, the warning device emits a warning signal to cause the housing to display a second color, characterized in that the hydrogen generation system according to claim 7.

12. Furthermore, the hydrogen generation system according to claim 7 includes a plurality of hydrogen generators, each hydrogen generator including a housing and a warning device, the warning device is provided inside the hydrogen generator, the hydrogen gas detection device is connected to the plurality of hydrogen generators by wireless transmission, and thereby, when the hydrogen gas detection device detects that the hydrogen gas concentration around the plurality of hydrogen generators exceeds a predetermined threshold of hydrogen gas concentration, the warning device causes each of the plurality of hydrogen generators to display the second color on the housing.

13. The hydrogen generation system according to claim 7, characterized in that the warning device is an audio generating member that emits a warning sound as a warning signal when the hydrogen gas detection device detects that the hydrogen gas concentration exceeds a predetermined threshold of hydrogen gas concentration.

14. The hydrogen generation system according to claim 9, further comprising a capacitive water level meter for detecting the water level inside the housing of the hydrogen water generator when the housing is installed in the hydrogen generation device.

15. The hydrogen generation system according to claim 14, further comprising a control module connected to the capacitive water level meter, wherein the capacitive water level meter includes a high-level detector and a low-level detector, and the control module controls the hydrogen generation device to stop generating the hydrogen-containing gas when the housing is removed from the hydrogen generation device and the high-level detector and the low-level detector can no longer detect the high and low water levels in the cup.

16. The hydrogen generator further, A tank for storing water, An electrolytic cell is provided inside the tank, which receives water from the tank and generates the hydrogen-containing gas by electrolyzing the water, An integrated flow path device is stacked vertically on the tank and communicates with the tank to receive the hydrogen-containing gas from the tank, A condensing filter device connected to the integrated flow channel device receives and filters the hydrogen-containing gas from the integrated flow channel device, The hydrogen generation system according to claim 7, characterized in that it includes a humidifier which is stacked vertically on the tank, located between the tank and the integrated flow channel device, and connected to the integrated flow channel device, and which receives and humidifies the filtered hydrogen-containing gas.

17. The hydrogen generation system according to claim 16, wherein the condensing filter device has a condensing channel, and the condensing filter device is removablely fitted into the integrated channel device to receive hydrogen-containing gas from the integrated channel device and to filter the hydrogen-containing gas in the condensing channel.

18. The hydrogen generation system according to claim 16, further comprising an atomizer, the atomizer being connected to the integrated flow channel device, and receiving the humidified hydrogen-containing gas from the integrated flow channel device, mixing the generated atomized gas with the hydrogen-containing gas to form a healthcare gas, and discharging it.