CN221330922U - Soup pot for cooking hydrogen-rich water - Google Patents

Abstract

The utility model discloses a soup pot for cooking hydrogen-rich water, which relates to the field of hydrogen-rich water application equipment, and comprises a base, a soup pot main body and a soup pot cover body; the soup pot main body is arranged on the base, and the soup pot cover body covers the soup pot main body; the base still includes heating device, hydrogen intake pipe and hydrogen outlet duct, and hydrogen intake pipe sets up in heating device's bottom, and the hydrogen outlet duct sets up the center at heating device top. The hydrogen inlet pipe and the hydrogen outlet pipe are arranged at the bottom of the soup pot main body, the hydrogen inlet pipe is communicated with an external hydrogen source, and the hydrogen outlet pipe continuously conveys hydrogen from the bottom of the soup pot main body to the inner cavity of the soup pot main body, so that hydrogen-rich water cooking food is realized. The utility model can not consume water for cooking food when in use, can not change the ratio of food materials to water, and can not cause potential safety hazard because of too low water quantity caused by hydrogen production by water electrolysis.

Description

Soup pot for cooking hydrogen-rich water

Technical Field

The utility model belongs to the field of hydrogen-rich water application equipment, and particularly relates to a soup pot for cooking hydrogen-rich water.

Background

With the progress of the age science and technology, the life pace of people is more and more compact, and the physical and psychological pressure of people is more and more high, so people are increasingly concerned about how to care to have a healthy body. In recent years, a theory that water containing a large amount of hydrogen gas can effectively eliminate active oxygen which is considered as a cause of cancer and other various diseases has been published and attracting attention in the medical field.

As mentioned above, hydrogen rich Water is Water containing a certain amount of Hydrogen molecules, also known as Water, also known as "Hydrogen Water". Hydrogen is a colorless, odorless, nontoxic, and odorless gas. The unique nature of hydrogen determines that hydrogen has many biological advantages. A more obvious feature is the strong penetrability, which can easily enter any part in the cell such as nucleus and mitochondria. This is an important feature that hydrogen can be used for health care and physiotherapy.

Along with the increasing popularity of hydrogen-enriched water, it has been proposed to combine the effects of dietetic supplementation and physical therapy with hydrogen, and most of the existing hydrogen-enriched kettles are to electrolyze water in the kettles by arranging electrodes in the kettles, so as to generate hydrogen molecules, such as the patent of patent publication number CN 106235869B and the patent of patent application number CN115624276 a.

But through carrying out the electrolysis to the water in the pot can reduce the water yield in the pot in a large number to destroyed original food and water ratio, simultaneously, along with the rising of temperature, the solubility of hydrogen in water can reduce, if need guaranteeing the content of hydrogen, then need electrolyze a large amount of water, cause the gas pressure in the pot too high and the water yield is too low easily, has the potential safety hazard.

Disclosure of utility model

The utility model discloses a hydrogen-rich water soup pot, which has the same technical scheme as the same technical scheme, but aims to solve the problem that the water quantity in the existing hydrogen-rich pot can be reduced greatly when hydrogen is generated, and the utility model aims to provide a soup pot for cooking hydrogen-rich water.

The technical scheme adopted by the utility model is as follows:

A soup pot for hydrogen-rich water cooking comprises a base, a soup pot main body and a soup pot cover body; the soup pot main body is arranged on the base, and the soup pot cover body covers the soup pot main body; the base still includes heating device, hydrogen intake pipe and hydrogen outlet duct, and the hydrogen intake pipe sets up in heating device's bottom, and the hydrogen outlet duct sets up the center at heating device top, and the one end and the hydrogen intake pipe intercommunication of hydrogen outlet duct, the other end and the soup pot main part inner chamber intercommunication of hydrogen outlet duct.

Optionally, the heating device is provided with a main body tray, and the main body tray is provided with an anti-dry heating element.

Optionally, a split cover is arranged at the center of the heating device; one end of the split cover, which is far away from the heating device, is positioned in the soup pot main body; the split cover is sleeved on the hydrogen outlet pipe; the split cover is provided with movable balls, and the outer diameter of each ball is larger than the drift diameter of the hydrogen outlet pipe.

Optionally, a temperature sensor is arranged on the base, and the temperature sensor is used for controlling the temperature in the soup pot main body.

Alternatively, the base is embedded at the bottom of the mounting seat, the top end of the mounting seat is hinged with a top cover, the soup pot cover body is embedded in the top cover, and the heating device is embedded in the mounting seat; a top cover is rotatably arranged at the top end of the mounting seat and used for covering and sealing the soup cooker body; an electrolytic tank and a water storage tank are arranged in the mounting seat, the electrolytic tank and the water storage tank are both arranged in the mounting seat, a water inlet pipe of the water storage tank is connected with an external water source, and a water outlet pipe of the water storage tank is connected with the electrolytic tank; the electrolyzer is used for generating hydrogen by electrolysis of water, and the hydrogen outlet end of the electrolyzer is communicated with the hydrogen inlet pipe.

Optionally, a hydrogen return pipe is arranged on the top cover, and two ends of the hydrogen return pipe are respectively communicated with the soup pot main body and the hydrogen inlet pipe.

Optionally, an air pump is arranged between the electrolytic tank and the soup pot, the air inlet end of the air pump is communicated with the hydrogen outlet end of the electrolytic tank, and the air outlet end of the air pump is communicated with the inner cavity of the soup pot; the hydrogen return pipe is communicated with the air inlet end of the air pump, and the hydrogen outlet end of the electrolytic tank passes through the base and is communicated with the inside of the soup pot main body.

Optionally, a filter is arranged between the water storage tank and the electrolytic tank.

Alternatively, the oxygen outlet end of the electrolytic tank is connected with the top end of the water storage tank; the water storage tank is provided with a first liquid level sensor and a second liquid level sensor.

Optionally, a safety valve is further arranged on the top cover and used for releasing the pressure in the inner cavity of the soup pot.

The beneficial effects of the utility model are as follows:

The utility model provides a soup pot for hydrogen-rich water cooking, which comprises a base, a soup pot main body and a soup pot cover body, wherein the base is provided with a bottom; the soup pot main body is arranged on the base, and the soup pot cover body covers the soup pot main body; the base still includes heating device, hydrogen intake pipe and hydrogen outlet duct, and the hydrogen intake pipe sets up in heating device's bottom, and the hydrogen outlet duct sets up the center at heating device top, and the one end and the hydrogen intake pipe intercommunication of hydrogen outlet duct, the other end and the soup pot main part inner chamber intercommunication of hydrogen outlet duct. The hydrogen inlet pipe and the hydrogen outlet pipe are arranged at the bottom of the soup pot main body, the hydrogen inlet pipe is communicated with an external hydrogen source, and the hydrogen outlet pipe continuously conveys hydrogen from the bottom of the soup pot main body to the inner cavity of the soup pot main body, so that hydrogen-rich water cooking food is realized. The utility model can not consume water for cooking food when in use, can not change the ratio of food materials to water, and can not cause potential safety hazard because of too low water quantity caused by hydrogen production by water electrolysis.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic view of the internal structure of the present utility model.

Fig. 3 is a schematic view of the internal structure of another view of the present utility model.

FIG. 4 is a schematic diagram of the connection of the water storage tank, the filter and the electrolytic cell.

Fig. 5 is a schematic structural view of the base.

Fig. 6 is a schematic side view of a heating device.

Fig. 7 is a schematic top view of the heating device.

Fig. 8 is an exploded schematic view of the diverter housing and the heating device.

Fig. 9 is a schematic structural view of the base.

Fig. 10 is a schematic view of the internal structure of the top cover.

In the figure: 1-mounting seat, 2-soup pot, 21-base, 211-heating device, 2111-hydrogen inlet pipe, 2112-hydrogen outlet pipe, 2113-ball, 212-main body tray, 2121-dry burning prevention element, 213-split cover, 214-temperature sensor, 22-soup pot main body, 221-soup pot cover body, 222-return pipe, 223-exhaust hole, 23-relief valve, 3-air pump, 4-electrolytic tank, 5-filter, 6-water storage tank, 61-first liquid level sensor, 62-second liquid level sensor and 7-top cover.

Detailed Description

Embodiment one:

In this embodiment, as shown in fig. 5 to 9, the soup pot 2 includes a base 21, a soup pot body 22 and a soup pot cover 221, the base 21 is embedded at the bottom of the mounting base 1, the soup pot body 22 is mounted on the base 21, and the soup pot cover 221 is embedded in the top cover 7; the base 21 comprises a heating device 211, and the hydrogen outlet end of the electrolyzer 4 passes through the base 21 to be communicated with the interior of the soup pot main body 22. The base 21 includes hydrogen intake pipe 2111 and hydrogen outlet duct 2112, and hydrogen intake pipe 2111 sets up in the bottom of heating device 211, and hydrogen outlet duct 2112 sets up the center at heating device 211 top, and hydrogen outlet duct 2112's one end and hydrogen intake pipe 2111 intercommunication, hydrogen outlet duct 2112's the other end and the inner chamber intercommunication of a soup pot main part 22. By arranging the hydrogen inlet pipe 2111 and the hydrogen outlet pipe 2112 at the bottom of the soup pot main body 22, the hydrogen inlet pipe 2111 is communicated with the hydrogen source electrolytic tank 4, and the hydrogen outlet pipe 2112 continuously conveys hydrogen from the bottom of the soup pot main body 22 to the inner cavity of the soup pot main body 22, so that the hydrogen-rich water cooking food is realized. The utility model can not consume water for cooking food when in use, can not change the ratio of food materials to water, and can not cause potential safety hazard because of too low water quantity caused by hydrogen production by water electrolysis.

Specifically, the heating device 211 is a heating resistance wire, the heating resistance wire is in a vortex shape, the hydrogen outlet pipe 2112 is positioned at the center of the heating resistance wire, and the hydrogen outlet pipe 211 is not in direct contact with the heating resistance wire. In use, the heating resistance wire heats the bottom wall of the soup pot body 22.

In the present embodiment, the heating device 211 is centrally provided with a split cover 213; one end of the split cover 213, which is far away from the heating device 211, penetrates through the bottom wall of the soup pot main body 22 and is positioned in the soup pot main body 22; the split cover 213 is sleeved on the hydrogen outlet pipe 2112; the shunt housing 213 is provided with movable balls 2113, the outer diameter of the balls 2113 being larger than the diameter of the hydrogen outlet pipe 2112. The ball 2113 makes hydrogen only enter the main body 22 from the hydrogen outlet pipe 2112 in one direction, but food and water in the inner cavity of the main body 22 cannot enter the hydrogen outlet pipe 2112, so as to effectively prevent liquid in the main body 22 from reversely flowing into the hydrogen outlet pipe 2112.

In this embodiment, the side wall of the split cover 213 at one end of the inner cavity of the soup pot body 22 is provided with a plurality of air outlets, and the hydrogen is discharged from the air outlets on the side wall of the split cover 213. The air outlet holes of the split cover 213 are used for dispersing and outputting the hydrogen output by the hydrogen outlet pipe 2112 to all directions of the inner cavity of the soup pot main body 22.

Specifically, when the hydrogen pressure in the hydrogen outlet pipe 2112 is higher than the pressure of the ball 2113 and the inner cavity of the soup pot main body 22, the hydrogen in the hydrogen outlet pipe 2112 pushes the ball 2113, so that the ball 2113 is not blocked on the hydrogen outlet pipe 2112 any more; when the pressure of the hydrogen in the hydrogen outlet pipe 2112 is smaller than the pressure of the ball 2113 and the inner cavity of the soup pot main body 22, the ball 2113 is blocked on the hydrogen outlet pipe 2112 under the influence of the gravity of the ball 2113 and the gravity of the water and food in the soup pot main body 22, so that the liquid in the soup pot main body 22 cannot be reversely connected into the hydrogen outlet pipe 2112.

In the present embodiment, the heating device 211 is provided with a main body tray 212, and the main body tray 212 is provided with a dry burning prevention element 2121. The main body tray 212 is used for supporting the bottom wall of the soup pot main body 22, and heating the bottom wall of the soup pot main body 22 through the main body tray 212, the dry-heating preventing element 2121 is a temperature sensing element, and the dry-heating preventing element 2121 is electrically connected with the heating device 211, and when the dry-heating preventing element 2121 detects that the temperature of the bottom wall of the soup pot main body 22 is too high, the power supply of the heating device 211 is disconnected.

In the present embodiment, a temperature sensor 214 is disposed on the base 21, the temperature sensor 214 is used for measuring the temperature of the liquid in the main body 22, the temperature sensor 214 is electrically connected with the heating device 211, and cooking of different food materials in the main body 22 can be achieved through the temperature sensor 214. When the set temperature of the temperature sensor 214 is reached, the power supply to the heating device 211 is turned off.

Embodiment two:

The embodiment provides a specific scheme for the installation structure of the soup pot and the hydrogen source on the basis of the first embodiment.

In this embodiment, a soup pot for cooking hydrogen-rich water as shown in fig. 1 to 4 comprises a mounting seat 1, a soup pot 2, an electrolytic tank 4, a water storage tank 6 and a top cover 7; the soup pot 2 is arranged on the mounting seat 1, the top end of the mounting seat 1 is rotatably provided with a top cover 7, and the top cover 7 is used for covering and sealing the soup pot 2; the electrolytic tank 4 and the water storage tank 6 are both arranged in the mounting seat 1, the water inlet pipe of the water storage tank 6 is connected with an external water source, and the water outlet pipe of the water storage tank 6 is connected with the electrolytic tank 4; the electrolytic tank 4 is used for electrolyzing water to generate hydrogen, and the hydrogen outlet end of the electrolytic tank 4 is communicated with the inner cavity of the soup pot 2; the soup pot 2 comprises a heating device 211, and the heating device 211 is embedded in the mounting seat 1; the top cover 7 is provided with a hydrogen return pipe 222, and the hydrogen return pipe 222 is communicated with the inner cavity of the soup pot 2. When in use, the water is electrolyzed by the electrolytic tank 4 to generate hydrogen, and the hydrogen is continuously conveyed into the soup pot 2; the heating device 211 is used for heating the food materials and the water in the soup pot 2, and along with the temperature rise, the hydrogen can escape from the water, but the escaped hydrogen can be recycled to the inside of the soup pot 2 along with the return pipe 222, and the hydrogen can be in more full contact with the food materials through the recycling flow, so that the hydrogen can fully penetrate into the food materials, and more hydrogen is mixed in the food materials, thereby realizing the effective combination of the effects of dietetic invigoration and hydrogen physiotherapy; meanwhile, as the electrolysis of the electrolytic tank 4 is continued, the concentration of hydrogen in the whole soup pot 2 is increased, and the pressure is increased, so that the solubility of hydrogen in boiling water can be improved, and the hydrogen content in food materials and water is further improved.

Embodiment III:

The embodiment provides a specific scheme for controlling the pressure in the soup pot on the basis of the first embodiment.

In this embodiment, as shown in fig. 2, 3 and 10, an air pump 3 is arranged between the electrolytic tank 4 and the soup pot 2, the air inlet end of the air pump 3 is communicated with the hydrogen outlet end of the electrolytic tank 4, and the air outlet end of the air pump 3 is communicated with the inner cavity of the soup pot 2; the hydrogen return pipe 222 communicates with the intake end of the air pump 3. The air inlet end of the air pump 3 is simultaneously communicated with the return pipe 222 and the hydrogen outlet end of the electrolytic tank 4 through a three-way joint. The air pump 3 can guide the hydrogen in the soup pot main body 22 and the return pipe 222 so that the hydrogen can only enter the return pipe 222 from the soup pot cover 221 for circulation.

In this embodiment, as shown in fig. 10, the soup pot 2 is sealed by the soup pot cover 221 in normal use, the soup pot cover 221 is embedded in the top cover 7, the soup pot cover 221 is provided with an exhaust hole 223, the top cover 7 is further provided with a safety valve 23, and the safety valve 23 is communicated with the inner cavity of the soup pot 2 through the exhaust hole 223. The safety valve 23 is used for releasing the pressure in the inner cavity of the soup pot 2. Because the electrolytic bath 4 can continuously generate hydrogen when in use, after the pressure in the inner cavity of the soup pot main body 22 overcomes the gravity of the safety valve 23, the pressure in the soup pot main body 22 can spring the safety valve 23, so that the pressure in the inner cavity of the soup pot main body 22 is released; when the pressure in the inner cavity of the soup pot main body 22 is smaller than the gravity of the safety valve 23, the safety valve 23 is restored to the initial position, and at this time, the hydrogen in the inner cavity of the soup pot main body 22 circulates only through the return pipe 222.

Embodiment four:

The embodiment provides an alternative to the specific structure of the water storage tank on the basis of any of the embodiments.

In this embodiment, as shown in fig. 2 to 4, a filter 5 is provided between the water storage tank 6 and the electrolytic bath 4. The oxygen outlet end of the electrolytic tank 4 is connected with the top end of the water storage tank 6; the water storage tank 6 is provided with a first liquid level sensor 61 and a second liquid level sensor 62. The water inlet end of the water storage tank 6 is connected with a tap water pipe, and the filter 5 can filter impurities in water to prevent the impurities from accumulating in the electrolytic tank 4. The first liquid level sensor 61 is used for performing low water level early warning, and when the first liquid level sensor 61 detects that a signal disappears, a valve connected with the water storage tank 6 is opened to supplement water source for the water storage tank 6; the second liquid level sensor 62 is used for carrying out high water level early warning, when the liquid level overflows the height of the second liquid level sensor 62, the second liquid level sensor 62 detects signals, the valve connected with the fish water outlet pipe 6 is closed, and the outside stops supplementing water sources into the water storage tank 6.

In this embodiment, specifically, the bottom end of the water storage tank 6 communicates with the filter 5, and the bottom end of the filter 5 communicates with the electrolytic tank 4. The oxygen outlet end of the electrolytic tank 4 is communicated with the water storage tank 6, so that the water pressure in the water storage tank 6 can be effectively maintained. Meanwhile, the top end of the water storage tank 6 is also provided with an oxygen discharge safety valve (not shown in the figure) for preventing the pressure in the water storage tank 6 from being too high.

Embodiment four:

The embodiment provides an alternative scheme for the specific structure of the soup pot on the basis of any embodiment.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

While embodiments of the present utility model have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the utility model, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the utility model.

Claims (10)

1. A soup pot for hydrogen-rich water cooking, which is characterized in that: the soup pot (2) comprises a base (21), a soup pot main body (22) and a soup pot cover body (221);

The soup pot main body (22) is arranged on the base (21), and the soup pot cover body (221) covers the soup pot main body (22);

The base (21) further comprises a heating device (211), a hydrogen inlet pipe (2111) and a hydrogen outlet pipe (2112), the hydrogen inlet pipe (2111) is arranged at the bottom of the heating device (211), the hydrogen outlet pipe (2112) is arranged at the center of the top of the heating device (211), one end of the hydrogen outlet pipe (2112) is communicated with the hydrogen inlet pipe (2111), and the other end of the hydrogen outlet pipe (2112) is communicated with the inner cavity of the soup pot body (22).

2. A soup pot for hydrogen rich water cooking according to claim 1, characterized in that the heating device (211) is provided with a main body tray (212), and the main body tray (212) is provided with a dry burning preventing element (2121).

3. Soup pot for hydrogen-rich water cooking according to claim 1, characterized in that the heating device (211) is centrally provided with a split cover (213);

One end of the split cover (213) far away from the heating device (211) is positioned in the soup pot main body (22);

The split cover (213) is sleeved on the hydrogen outlet pipe (2112);

The split cover (213) is provided with movable balls (2113), and the outer diameter of each ball (2113) is larger than the diameter of the hydrogen outlet pipe (2112).

4. Soup pot for hydrogen-rich water cooking according to claim 1, characterized in that a temperature sensor (214) is provided on the base (21), which temperature sensor (214) is used for the temperature in the soup pot body (22).

5. The soup pot for cooking hydrogen-enriched water according to claim 1, wherein the base (21) is embedded at the bottom of the mounting seat (1), the top end of the mounting seat (1) is hinged with a top cover (7), the soup pot cover body (221) is embedded in the top cover (7), and the heating device (211) is embedded in the mounting seat (1);

A top cover (7) is rotatably arranged at the top end of the mounting seat (1), and the top cover (7) is used for covering and enabling the soup pot cover body (221) to seal the soup pot main body (22);

An electrolytic tank (4) and a water storage tank (6) are arranged in the mounting seat (1), the electrolytic tank (4) and the water storage tank (6) are arranged in the mounting seat (1), a water inlet pipe of the water storage tank (6) is connected with an external water source, and a water outlet pipe of the water storage tank (6) is connected with the electrolytic tank (4);

The electrolytic tank (4) is used for electrolyzing water to generate hydrogen, and a hydrogen outlet end of the electrolytic tank (4) is communicated with the hydrogen inlet pipe (2111).

6. The soup pot for cooking hydrogen-rich water according to claim 5, wherein a hydrogen return pipe (222) is arranged on the top cover (7), and two ends of the hydrogen return pipe (222) are respectively communicated with the soup pot main body (22) and the hydrogen inlet pipe (2111).

7. The soup pot for cooking hydrogen-rich water according to claim 6, wherein an air pump (3) is arranged between the electrolytic tank (4) and the soup pot (2), the air inlet end of the air pump (3) is communicated with the hydrogen outlet end of the electrolytic tank (4), and the air outlet end of the air pump (3) is communicated with the inner cavity of the soup pot (2);

The hydrogen return pipe (222) is communicated with the air inlet end of the air pump (3), and the hydrogen outlet end of the electrolytic tank (4) penetrates through the base (21) to be communicated with the inside of the soup pot main body (22).

8. Soup pot for hydrogen rich water cooking according to claim 5, characterized in that a filter (5) is arranged between the water storage tank (6) and the electrolysis cell (4).

9. A soup pot for hydrogen-rich water cooking according to claim 5, characterized in that the oxygen outlet end of the electrolyzer (4) is connected with the top end of the water storage tank (6);

The water storage tank (6) is provided with a first liquid level sensor (61) and a second liquid level sensor (62).

10. The soup pot for cooking hydrogen-rich water according to claim 5, wherein the top cover (7) is further provided with a safety valve (23), and the safety valve (23) is used for releasing the pressure of the inner cavity of the soup pot (2).