CN111616594A - Soda water machine and soda water manufacturing method - Google Patents

Abstract

The invention relates to the technical field of household appliances, in particular to a soda water machine and a soda water manufacturing method, which comprise the following steps: the liquid storage device is used for storing liquid; a gas storage device for storing carbon dioxide; the reaction device is communicated with the liquid storage device and the gas storage device, and liquid in the liquid storage device is mixed with carbon dioxide in the gas storage device in the reaction device; the temperature sensing device is used for detecting a temperature signal of the reaction device and/or the liquid storage device; the temperature sensing device feeds the temperature signal back to the control device, and the control device is used for controlling the conduction time of the gas storage device and the reaction device according to the temperature signal. According to the soda water machine and the soda water manufacturing method, the aeration time is controlled through the change of the liquid temperature, soda water with different carbonic acid contents is manufactured, different using requirements of users on the soda water are met, and the soda water machine and the soda water manufacturing method are safe and reliable.

Description

Soda water machine and soda water manufacturing method

Technical Field

The invention relates to the technical field of household appliances, in particular to a soda water machine and a soda water manufacturing method thereof.

Background

As is known, CO2 is dissolved in water to generate carbonic acid, and according to this principle, some soda water machines are produced, but the existing soda water machines generally form soda water by manually performing water feeding, air intake and the like.

The existing soda water machine has more defects, wherein carbonic acid is unstable at normal temperature and is easy to decompose, and the decomposed CO2 is released, so that the solubility is reduced, and the mouthfeel is influenced. Different temperatures and different solubilities of CO2 can produce soda water meeting the requirement without knowing what conditions the user can produce.

Disclosure of Invention

The invention aims to provide a soda machine and a soda manufacturing method, wherein soda with different carbonic acid amounts is manufactured by controlling the aeration time through the change of liquid temperature, different using requirements of users on the soda are met, and the soda machine is safe and reliable.

In one aspect, the present invention provides a soda machine, including:

the liquid storage device is used for storing liquid;

a gas storage device for storing carbon dioxide;

the reaction device is communicated with the liquid storage device and the gas storage device, and liquid in the liquid storage device is mixed with carbon dioxide in the gas storage device in the reaction device;

the temperature sensing device is used for detecting a temperature signal of the reaction device and/or the liquid storage device;

the temperature sensing device feeds the temperature signal back to the control device, and the control device is used for controlling the conduction time of the gas storage device and the reaction device according to the temperature signal.

Furthermore, the control device is also used for controlling the connection or disconnection between the gas storage device and the reaction device.

Further, a liquid level sensor is arranged in the reaction device and used for detecting a liquid level signal in the reaction device;

the liquid level sensor feeds back the liquid level signal to the control device, and the control device is further used for controlling the connection or disconnection of the liquid storage device and the reaction device according to the liquid level signal.

Further, a pressure sensor is arranged in the reaction device and used for detecting a pressure signal in the reaction device;

the pressure sensor feeds the pressure signal back to the control device, and the control device is also used for controlling the connection or disconnection of the gas storage device and the reaction device according to the pressure signal.

Further, the temperature sensing device is arranged in the liquid storage device and is an NTC thermistor; and/or the presence of a gas in the gas,

the temperature sensing device is arranged in the reaction device and is a temperature sensor.

Further, the pressure relief device is further comprised, and the pressure relief device is electrically connected with the control device;

under the control of the control device, the pressure relief mechanism can control the reaction device to be connected or disconnected with the external environment.

Further, the reaction device is provided with a pressure relief opening and an installation cavity, and the pressure relief opening is communicated with the external environment through the installation cavity;

the pressure relief mechanism comprises a pressure relief mechanism body,

the pressure relief valve comprises a pressure relief valve rod and a plugging part, and the plugging part is positioned in the installation cavity and can move in the installation cavity so as to plug the pressure relief opening and the installation cavity or conduct the pressure relief opening and the installation cavity;

the pressure relief driving part is connected with the pressure relief valve rod and is used for driving the pressure relief valve to move;

the pressure relief driving part comprises a pressure relief driving motor, a pressure relief pressure lever and a pressure relief cam, and the pressure relief driving motor is used for driving the pressure relief cam to rotate;

the pressure relief cam and the pressure relief valve rod are respectively connected to two ends of the pressure relief pressure rod, the pressure relief pressure rod can rotate around a first rotation center, and the pressure relief valve rod is positioned between the first rotation center and the pressure relief cam;

the pressure relief mechanism further comprises a first elastic part, and two ends of the first elastic part are respectively abutted to the inner wall of the mounting cavity and the pressure relief valve.

Further, the soda machine further comprises a water inlet mechanism, and the water inlet mechanism is used for controlling the connection or disconnection between the liquid storage device and the reaction device under the control of the control device;

wherein the water inlet mechanism comprises a water inlet pipe,

the water inlet pump is electrically connected with the control device;

the one-way valve is arranged on the communicating pipeline between the water inlet pump and the reaction device and used for realizing one-way liquid inlet of the liquid storage device into the reaction device.

Further, the soda machine further comprises an air inlet mechanism, and the air inlet mechanism is used for controlling the connection or disconnection between the air storage device and the reaction device under the control of the control device;

the gas storage device is provided with a gas outlet and a plugging cavity, and the gas outlet is communicated with the reaction device through the plugging cavity;

wherein the air inlet mechanism comprises an air inlet pipe,

the sealing part is positioned in the plugging cavity and can move in the plugging cavity to plug the plugging cavity or conduct the plugging cavity so as to conduct or disconnect the gas outlet and the reaction device;

the end part of the ejector rod is matched with the sealing part to push the sealing part to move in the plugging cavity;

the air inlet driving component is connected with the ejector rod and is used for driving the ejector rod to move;

the air inlet driving component comprises an air inlet driving motor, an air inlet pressure rod and an air inlet cam, and the air inlet driving motor is used for driving the air inlet cam to rotate;

the air inlet cam and the ejector rod are respectively connected with two ends of the air inlet pressure rod, the air inlet pressure rod can rotate around a second rotation center, and the ejector rod is located between the second rotation center and the air inlet cam.

The air inlet mechanism further comprises a second elastic component, and two ends of the second elastic component are respectively abutted against the sealing part and the inner wall of the plugging cavity.

Further, the method comprises the following steps of,

the joint part is provided with a first joint, and the first joint is connected with the reaction device;

the joint part is also provided with a second joint, a third joint and a fourth joint, the second joint is used for communicating the liquid storage device with the reaction device, the third joint is used for communicating the gas storage device with the reaction device, and the fourth joint is used for communicating the reaction device with the outside;

the gas needle penetrates through the third joint and at least partially extends into the inner cavity of the reaction device so as to realize the communication between the gas storage device and the reaction device;

wherein, the liquid level sensor is arranged on the outer wall of the air needle.

The invention also provides a soda water manufacturing method, which is applied to any one of the soda water machines and comprises the following steps:

s11: detecting a temperature signal of liquid in the reaction device and/or the liquid storage device;

s21: and judging the temperature interval where the temperature signal is positioned, and controlling the preset conduction time of the reaction device and the gas storage device according to the temperature interval.

Further, in step S21, when the temperature signal is below 5 ℃, controlling the preset on-time to be 2.5-3.5 seconds;

when the temperature signal is at 5-15 ℃, controlling the preset conduction time to be 2-2.5 seconds;

when the temperature signal is at 15-45 ℃, controlling the preset conduction time to be 1.5-2 seconds;

and when the temperature signal is above 45 ℃, controlling the preset conduction time within 1.5 seconds.

Further, in S21, it is further determined whether the temperature signal reaches a first critical temperature and a second critical temperature, and if so, the gas storage device and the reaction device are disconnected;

wherein the first critical temperature is 0 ℃ and the second critical temperature is 50 ℃.

Further, a liquid level sensor is arranged in the reaction device and used for detecting a liquid level signal in the reaction device;

before step S11, the method further includes:

s10: and when the liquid level signal reaches a water level critical signal, the liquid storage device is controlled to be disconnected with the reaction device.

Further, a pressure sensor is arranged in the reaction device and used for detecting a pressure signal in the reaction device;

in step S21, the method further includes:

s211: and when the pressure signal reaches a pressure critical signal, controlling the gas storage device to be disconnected with the reaction device.

Further, in step S21, after the conduction time between the gas storage device and the reaction device reaches the preset conduction time, the method further includes:

s22: the gas storage device is disconnected with the reaction device;

s23: and carrying out pressure relief operation on the reaction device.

The invention has the beneficial effects that:

the present invention provides a soda machine, including: the liquid storage device is used for storing liquid; the gas storage device is used for storing carbon dioxide; the reaction device is communicated with the liquid storage device and the gas storage device, and liquid in the liquid storage device is mixed with carbon dioxide in the gas storage device in the reaction device; the temperature sensing device is used for detecting a temperature signal of the reaction device and/or the liquid storage device; the temperature sensing device feeds back the temperature signal to the control device, and the control device is used for controlling the conduction time of the gas storage device and the reaction device according to the temperature signal. Specifically, the gas storage device and the liquid storage device are respectively communicated with the reaction device, the temperature sensing device feeds back a detected temperature signal to the control device, and the communication time between the gas storage device and the reaction device is controlled and adjusted under the action of the control device, so that the time for filling carbon dioxide into the reaction device by the gas storage device is controlled according to different temperatures. Presetting temperature in the control device, and corresponding to different inflation time at different preset temperatures; after the temperature signal is transmitted to the control device, the temperature signal is matched with the preset temperature, so that carbon dioxide with different amounts is charged. By adopting the matching structure, the aeration time is controlled through the change of the liquid temperature, the soda water with different carbonic acid contents is prepared, the different use requirements of users on the soda water are met, and the method is safe and reliable.

The invention also provides a soda water manufacturing method, which can achieve the same effect as a soda water machine and is not repeated herein.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is an overall view of a soda machine provided in an embodiment of the present invention;

FIG. 2 is a schematic view of the connection and matching inside the soda machine according to the embodiment of the present invention;

FIG. 3 is a schematic view of the connection and the fitting of the joint of the soda machine in the portion A of FIG. 2 according to the embodiment of the present invention;

FIG. 4 is an enlarged view of a portion of the gas needles extending into the reaction apparatus of FIG. 3;

FIG. 5 is a schematic view of the combination of the upper cover plate of the body of the soda machine structure of FIG. 1 with an opened partial structure;

FIG. 6 is an enlarged view of a portion of FIG. 5B showing an opened upper cover of the soda machine body;

FIG. 7 is a view of the structure of the upper cover plate and the opened side plate of the soda machine body;

FIG. 8 is a schematic view of the connection and matching inside the soda machine with the joint removed according to the embodiment of the present invention;

FIG. 9 is a schematic view of the internal connection of the soda machine with the joint portion removed in an inflated state according to the embodiment of the present invention;

fig. 10 is a schematic view of the internal connection in a pressure-released state of the soda machine with the joint removed according to the embodiment of the present invention.

Icon:

1-a liquid storage device;

2-gas storage means;

21-air outlet;

22-blocking the cavity;

3-a reaction device;

4-a control device;

41-a button;

5-a fuselage;

6-a water inlet mechanism;

61-a water inlet pump;

62-a one-way valve;

7-an air intake mechanism;

71-an air inlet pressure lever;

72-an intake cam;

73-an air intake drive motor;

74-a top rod;

75-sealing piece;

76-a second center of rotation;

77-a fixing rod;

78-a second elastic member;

8-a pressure relief mechanism;

81-pressure relief pressure lever;

82-a pressure relief cam;

83-relief drive motor;

84-a pressure relief valve stem;

85-a blocking part;

86-a first elastic member;

87-first center of rotation;

9-air needle;

91-air tap;

10-a joint part;

101-a first joint;

102-a second joint;

103-a third linker;

104-fourth connector/relief port;

105-a mounting cavity;

106-air leakage port;

11-a liquid level sensor;

12-a temperature sensing device;

121-NTC thermistor;

122-a temperature sensor;

13-pressure sensor.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "inside", "outside", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and operate, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 and 2, the present embodiment provides a soda machine including: the liquid storage device 1 is used for storing liquid; the gas storage device 2 is used for storing carbon dioxide; a reaction device 3 (the so-called reaction refers to a physical reaction that carbon dioxide dissolves in water to form carbonic acid, and does not involve a chemical reaction) which is communicated with the liquid storage device 1 and the gas storage device 2, and the liquid in the liquid storage device 1 is mixed with the carbon dioxide in the gas storage device 2 in the reaction device; the temperature sensing device 12 is used for detecting a temperature signal of the reaction device 3 and/or the liquid storage device 1 by the temperature sensing device 12; the control device 4 and the temperature sensing device 12 feed back the temperature signal to the control device 4, and the control device 4 is used for controlling the conduction time of the gas storage device 2 and the reaction device 3 according to the temperature signal. Specifically, the gas storage device 2 is disposed in the body 5, and when the carbon dioxide in the gas storage device 2 is used up, the carbon dioxide can be taken out from the body 5 for replacement, or can be directly disposed in the body 5, and the corresponding connection port position is opened to perform an inflation operation on the gas storage device 2, which is not specifically limited herein. In addition, the liquid storage device 1 and the reaction device 3 are both arranged outside the machine body 5, so that water can be added at any time, and the reaction device 3 can be detached.

Therefore, the gas storage device 2 and the liquid storage device 1 are respectively communicated with the reaction device 3 through the machine body 5, the control device 4 is arranged on the machine body 5, and the temperature sensing device 12 feeds back the detected temperature signal to the control device 4. Under the action of the control device 4, the communication time between the gas storage device 2 and the reaction device 3 is controlled and adjusted, so that the time for charging carbon dioxide into the reaction device 3 by the gas storage device 2 is controlled according to different temperatures. Presetting temperatures in the control device 4, and corresponding to different preset conduction times at different preset temperatures; after the temperature signal is transmitted to the control device 4, the temperature signal is matched with the preset temperature, so that carbon dioxide with different quantities is filled. By adopting the matching structure, the aeration time is controlled through the change of the liquid temperature, the soda water with different carbonic acid contents is prepared, the different use requirements of users on the soda water are met, and the method is safe and reliable.

More specifically, as shown in fig. 4 and 7, when the temperature sensing device 4 is only located in the liquid storage device 1, it is an NTC thermistor 121, which is located in the liquid storage device 1 near the liquid outlet, the liquid entering the reaction device 3 is only limited to flow from the liquid storage device 1, and the detected temperature in the liquid storage device 1 is the temperature of the liquid in the reaction device 3. And when the detected temperature signal is below 5 ℃, the temperature signal is fed back to the control device 4, the control device prompts a user, the taste of the formed carbonic acid is the best, the gas content of the carbon dioxide is the most saturated, and the drinking is most suitable, if the user has a drinking requirement, the corresponding button 41 of the control device 4 is pressed, the control device 4 automatically extracts the corresponding preset conduction time according to the temperature signal fed back at the moment, then the operation is started, the liquid in the liquid storage device 1 is filled into the reaction device 3, then the conduction time of the gas storage device 2 and the reaction device 3 is controlled, and the gas is filled, so that the steam water suitable for drinking is formed. When the detected temperature is above 5 ℃, the temperature signal is fed back to the control device 4, the control device 4 prompts a user that the taste of the carbonated water is bitter at the moment and the carbonated water is only suitable for external use, such as face washing, bath, vegetable washing and the like, so as to play a role in beautifying and sterilizing, at the moment, if the user has an external use requirement, the corresponding button 41 of the control device 4 is pressed, the control device 4 automatically extracts corresponding preset conduction time according to the temperature signal fed back at the moment, then starts working, fills the liquid in the liquid storage device 1 into the reaction device, then controls the conduction time of the gas storage device 2 and the reaction device 3, and inflates, thereby forming external soda.

When the temperature sensing device 12 is only in the reaction device 3, the temperature sensor 122 detects the temperature of the liquid in the reaction device 3, and feeds back a temperature signal to the control device 4. The liquid filled in the reaction device 3 may be the liquid in the liquid storage device 1, the liquid self-contained by the user, or the mixture of the two liquids, and in either case, the liquid detected by the temperature sensor 122 is the final liquid temperature in the reaction device 3, and the temperature signal is fed back to the control device 4. And when the detected temperature signal is below 5 ℃, the temperature signal is fed back to the control device 4, the control device 4 prompts a user, the taste of the formed carbonic acid is the best, the gas content of the carbon dioxide is the most saturated, and the drinking is most suitable, if the user has a drinking requirement, the control device 4 is pressed, the control device 4 automatically extracts corresponding preset conduction time according to the temperature signal fed back at the moment, then the work is started, the liquid in the liquid storage device 1 is filled into the reaction device 3, then the conduction time of the gas storage device 2 and the reaction device 3 is controlled, and the gas is filled, so that the steam water suitable for drinking is formed. When the detected temperature is above 5 ℃, the temperature signal is fed back to the control device 4, the control device 4 prompts a user that the taste of the carbonated water is bitter at the moment and the carbonated water is only suitable for external use, such as face washing, bath, vegetable washing and the like, so as to play a role in beautifying and sterilizing, at the moment, if the user has an external use requirement, the corresponding button 41 of the control device 4 is pressed, the control device 4 automatically extracts corresponding preset conduction time according to the temperature signal fed back at the moment, then starts working, fills the liquid in the liquid storage device 1 into the reaction device 3, then controls the conduction time of the gas storage device 2 and the reaction device 3, and inflates, thereby forming external soda.

When the temperature sensing devices 12 are arranged in the liquid storage device 1 and the reaction device 3, temperature signals detected in the reaction device 3 are used as main materials to adjust the inflating time, the temperature sensing device 12 in the liquid storage device 1 can be used as an auxiliary detection device, when the temperature sensing device 12 in the reaction device 3 breaks down, the control device 4 cannot receive corresponding temperature signals, the temperature sensing device 12 in the reaction device 3 is used as a standby, and the control device 4 starts the detection device to work normally so as to ensure the normal work of the soda machine and not delay the normal use.

Continuing with fig. 1 and 2, in another embodiment, the present application provides that the control device 4 is further configured to control the connection or disconnection between the gas storage device 2 and the reaction device 3. Two preset critical temperatures are arranged in the control device 4, namely the first critical temperature is 0 ℃, and when the temperature is lower than 0 ℃, liquid can be frozen, so that air cannot be filled and deaerated. The second critical temperature is 50 ℃, because the general reaction device is made of PET transparent plastic material, when the temperature is higher than 50 ℃, the material property is easy to change, the PET material becomes soft, the strength of the reaction device 3 becomes low, and the danger of bottle explosion can be generated when the reaction device is inflated. Therefore, when the temperature of the liquid in the reaction device 3 is detected to reach one of the critical temperatures, the temperature signal is fed back to the control device 4, the control device 4 controls the gas storage device 2 not to perform the carbon dioxide charging operation, the gas storage device 2 is disconnected from the reaction device 3, and the control device 4 prompts a user.

If the detected temperature of the reaction device 3 is between two critical temperatures and the temperature signal is below 5 ℃, controlling the preset conduction time to be 2.5-3.5 seconds, preferably 3 seconds; when the temperature signal is at 5-15 ℃, controlling the preset conduction time to be 2-2.5 seconds, preferably 2 seconds; when the temperature signal is at 15-45 ℃, controlling the preset conduction time to be 1.5-2 seconds, preferably 1.5 seconds; and when the temperature signal is above 45 ℃, controlling the preset conduction time within 1.5 seconds. Therefore, the aeration time is adjusted according to the temperature, so that the optimal content of carbon dioxide in the prepared soda water is ensured, and the carbon dioxide gas is saved.

In the above-mentioned manner of prompting the user through the control device 4, the body 5 may be provided with a plurality of signal lamps electrically connected to the control device 4, and when different temperature signals are detected and fed back to the control device 4, the control device 4 controls the signal lamps corresponding to the different signals to be turned on, so as to prompt the user that if soda water is produced at this time, the soda water is suitable for external use, drinking or not suitable for producing soda water, so as to prompt the user to produce soda water according to the requirement of the user. A display may be provided outside the body 5 to indicate different situations in the form of the display. Therefore, the user only needs to be prompted to directly know when the prepared soda water is suitable for external use, drinking or can not be prepared, and the specific limitation is not provided herein.

In another embodiment of the present invention, the body 5 is further provided with a display device for displaying a temperature signal and a button for manually setting a temperature, and is electrically connected to the control device 4, so that a user can automatically set the temperature of the carbonated water based on the displayed temperature of the temperature signal fed back, and start the carbonated water production when the control device 4 detects that the temperature of the liquid in the reaction device 3 is equal to the set temperature. If the ordinary user likes to use cool boiled water when using the soda machine, if the user puts the cool boiled water with too high temperature on the soda machine, the control device 4 can display the detected temperature signal in the reaction device 3 to the display device on the machine body 5 in a digital form. At this time, the user can set the temperature according to the requirement by manually adjusting the button for setting the temperature to carry out the inflation operation. More specifically, after the reaction device 3 added with cool boiled water is installed on the machine body 5, the temperature sensing device 12 detects the temperature of the liquid in the reaction device 3, feeds back the temperature signal to the control device 4, meanwhile, the temperature signal appears on the body 5 in a digital form, and after the user sees the corresponding number, a button for manually adjusting the set temperature is used for setting the temperature to be required for aeration at a certain temperature, after the aeration is finished, the liquid temperature in the reaction device 3 is naturally increased or decreased under the influence of the external environment temperature, when the liquid temperature in the reaction device 3 is the same as the manually set temperature, the aerated water machine is started to automatically complete the work of air inflation, and the user is reminded through the signal lamp or the sound after the work is completed, the reaction device 3 is immediately taken down, and the steam water in the reaction device is used, so that the waiting time of a user is reduced, and the use of the reaction device is convenient for the user.

However, if the user cannot timely remove the reaction device 3 after the charging is completed, and when the user uses the steam water in the reaction device 3, the temperature of the external environment is different from the temperature of the liquid in the reaction device 3, and the temperature of the steam water in the reaction device 3 gradually approaches the temperature of the external environment until the temperature is the same as the temperature of the liquid in the reaction device 3, the solubility of the carbonic acid can be changed in the process of the temperature change, and the requirement of the user for making the steam water at the constant temperature cannot be met, so that the user cannot timely remove the reaction device 3 after the charging is completed, the temperature sensing device in the reaction device 3 still continues to detect, and when the detected temperature signal deviates 1 ℃ from the temperature set by the user, the control device 4 reminds the user to timely remove the used steam water in a signal lamp or sound mode. If the temperature signal is not taken down, when the detected temperature signal deviates from the temperature set by the user by more than 5 ℃, the content of the carbon dioxide in the soda water does not belong to the optimal content, and the control device 4 prompts the user that the soda water can only be externally used in a signal lamp or display mode.

In order to avoid that the user misses the optimal time for taking the steam water after the user manually sets the inflation temperature and finishes inflation, a display panel is arranged on the machine body 5 and used for displaying the estimated time for finishing inflation, the user can do other things according to the estimated time, and the user can directly return to take the steam water after the estimated time is up, so that the optimal time for taking the steam water can not be missed. Specifically, after a user installs the reaction device 3 with cool boiled water into the body 5, the control device 4 is started, the temperature of liquid in the reaction device 3 is displayed outside the body 5, the user manually sets the proper temperature required by the user according to the situation to inflate, after the temperature setting is completed, the control device 4 automatically detects the temperature of the external environment and the temperature in the reaction device 3, the self-calculation analysis is carried out, the temperature is compared with the temperature set by the user, the time required by the temperature of the liquid in the reaction device 3 reaching the preset temperature in the environment is calculated, the time required by the completion is finally obtained, the time is displayed on the display panel, the user grasps the time for the completion of the inflation, even if the prompt tone is not heard, the user cannot miss the timely taking of the steam, and the waste of the aerated steam is avoided.

Or, sometimes the user needs to take the soda for external use or drinking, and the produced soda is wasted only when the user has idle for a certain time and the time is missed. Therefore, the user can set the time for taking the soda water and the purpose (drinking or external use) for taking the soda water in advance on the display panel by himself, the function similar to timing is achieved, the control device 4 detects the temperature of the liquid in the reaction device 3 according to the time set by the user, the temperature of the liquid in the reaction device 3 and the temperature of the external environment are judged, the temperature reduction or temperature rise curve of the liquid in the reaction device 3 is judged, the temperature range of the liquid in the reaction device 3 which needs to be added by himself by the user is calculated by combining the time set by the user, and the soda water meeting the user requirements is made after the fixed time. In addition, the temperature of the liquid in the reaction device 3 is not limited, and according to the requirement, before the time preset by the user, a heater or a condenser is arranged in the reaction device, the temperature of the liquid in the reaction device 3 is increased or decreased to a proper temperature, and then corresponding inflation is carried out, so that the production of the soda water is completed in a fixed time.

As a specific embodiment of the present application, as shown in fig. 2 and 3, a liquid level sensor 11 is disposed inside the reaction device 3, and the liquid level sensor 11 is used for detecting a liquid level signal inside the reaction device 3; the liquid level sensor 11 feeds back a liquid level signal to the control device 4, and the control device 4 is further used for controlling the connection or disconnection between the liquid storage device 1 and the reaction device 3 according to the liquid level signal. After a liquid level sensor 11 in the reaction device 3 detects a liquid level signal, the liquid level signal is fed back to the control device 4, namely the liquid in the reaction device 3 reaches a rated amount, if the liquid is filled from the liquid storage device 1, the control device 4 controls the liquid storage device 1 to stop filling water into the reaction device 3; if the user fills the liquid in the reaction device 3 by himself, the control device 4 controls the liquid in the liquid storage device 1 not to fill the liquid in the reaction device 3 any more. And starts the work of making soda water.

As a specific embodiment of the present application, as shown in fig. 2 and 3, a pressure sensor 13 is disposed in the reaction device 3, and the pressure sensor 13 is used for detecting a pressure signal in the reaction device 3; the pressure sensor 13 feeds back a pressure signal to the control device 4, and the control device 4 is further configured to control the connection or disconnection between the gas storage device 2 and the reaction device 3 according to the pressure signal. The soda machine also comprises a pressure relief mechanism 8, and the pressure relief mechanism 8 is electrically connected with the control device 4; under the control of the control device 4, the pressure relief mechanism 8 can control the reaction device 3 to be connected or disconnected with the external environment. The air pressure of the reaction device 3 after inflation and pressure relief is displayed through the control device 4, in the inflation process, the air pressure in the reaction device 3 is continuously detected, the pressure signal is fed back to the control device 4, if the detected pressure signal reaches the critical pressure signal, the signal is fed back to the control device 4, the control device 4 controls the gas storage device 2 and the reaction device 3 to be disconnected, the inflation is stopped, the reaction device 3 is communicated with the external environment through the pressure relief mechanism 8, the pressure relief is carried out, and the explosion of the reaction device is avoided. If in the inflating process, the pressure signal does not exceed the critical pressure signal, complete inflating work is carried out, after the inflating is completed, the gas storage device 2 is disconnected with the reaction device 3, the control device 4 starts the pressure relief mechanism 8 to carry out the pressure relief work after the inflating, after the pressure relief is completed, the reaction device 3 is taken down, internal steam and water can be taken, in this way, after the pressure relief, the internal pressure and the external pressure are relatively balanced, and the use safety of the appliance is improved. Meanwhile, when the pressure is released, if the pressure in the reaction device 3 does not reach the safe steam pressure, the user can be reminded through sound and light display, and the reaction device 3 can not be detached until the pressure is released to reach the safe steam pressure.

Specifically, as shown in fig. 6, 8, 9 and 10, the reaction device 3 has a pressure relief opening 104 and a mounting cavity 105, and the pressure relief opening 104 is communicated with the external environment through the mounting cavity 105; the pressure relief mechanism 8 comprises a pressure relief valve, which comprises a pressure relief valve rod 84 and a blocking part 85, wherein the blocking part 85 is positioned in the installation cavity 105 and can move in the installation cavity 105 to block the pressure relief opening 104 and the installation cavity 105 or conduct the pressure relief opening 104 and the installation cavity 105. The pressure relief mechanism 8 further comprises a pressure relief driving member connected to the pressure relief valve stem 84 for driving the pressure relief valve to move.

The pressure relief driving part comprises a pressure relief driving motor 83, a pressure relief pressure rod 81 and a pressure relief cam 82, and the pressure relief driving motor 83 is used for driving the pressure relief cam 82 to rotate; the pressure relief cam 82 and the pressure relief valve rod 84 are respectively connected to two ends of the pressure relief pressure lever 81, the pressure relief pressure lever 81 can rotate around a first rotation center 87, and the pressure relief valve rod 84 is positioned between the first rotation center 87 and the pressure relief cam 82; the two ends of the first elastic component 86 are respectively abutted against the inner wall of the mounting cavity 105 and the relief valve.

Specifically, the pressure relief cam 82 is rotated to realize the reciprocating rotation of the pressure relief pressure lever 81, so that the pressure relief pressure lever 81 controls the position of the pressure relief valve rod 84, and the pressure relief valve rod 84 moves relative to the mounting cavity. Preferably, the first rotation center 87 is fixed to the body 5, and the decompression lever 81 is rotatable about the first rotation center 87 with respect to the body 5. The movement direction of the pressure release valve rod 84 is parallel to the direction of the axis of the installation cavity, and the first elastic member 86 may be a spring having elasticity, and the spring passes through the pressure release valve rod 84, and two ends of the spring are respectively abutted between the blocking portion 85 and the inner wall of the installation cavity 105. The pressure relief pressure lever 81 is rotatably connected with the pressure relief valve rod 84, and the pressure relief valve rod 84 can be pushed to move relative to the mounting cavity 105 by the rotation of the pressure relief pressure lever 81. When the pressure relief valve rod 84 moves, the spring compresses or resets, so that the plugging part 85 plugs or opens the connection part of the pressure relief opening 104 and the installation cavity 105, and the reaction device 3 is connected or disconnected with the external environment, and pressure relief is realized. In order to discharge the internal pressure more conveniently, the side of the mounting cavity 105 is provided with a relief opening 106 communicated with the mounting cavity 105. Under the effect of the structure matching, the plugging is stable, the plugging part 85 at the pressure relief port 104 can bear large pressure under the action of external force, the sealing stability of the plugging is ensured, and the pressure relief is convenient to open, so that the stability is good.

This pressure release mechanism 8 during operation, controlling means 4 controls the output shaft rotation of pressure release driving motor 83, it rotates to drive pressure release cam 82, under the pressure effect of pressure release cam 82, pressure release depression bar 81 rotates around first rotation center 87, thereby drive the pressure release valve rod 84 axial motion of being connected with pressure release depression bar 81, so that pressure release mouth 104 is kept away from to shutoff portion 85, switch on external environment and 3 inner chambers of reaction unit, realize the pressure release, and shutoff portion 85 keeps away from the in-process of pressure release mouth 104 motion, can compress first elastomeric element 86, thereby when pressure release cam 82 disappears to pressure release depression bar 81's pressure, under the effect of first elastomeric element 86 resilience force, shutoff portion 85 can reset, realize the shutoff to pressure release mouth 104.

As a specific embodiment of the present application, as shown in fig. 2, fig. 3 and fig. 8, the soda machine further includes a water inlet mechanism 6, and under the control of the control device 4, the water inlet mechanism 6 is used for controlling the connection or disconnection between the liquid storage device 1 and the reaction device 3; the water inlet mechanism 6 comprises a water inlet pump 61, and the water inlet pump 61 is electrically connected with the control device 4; the check valve 62 and the check valve 62 are arranged on a communicating pipeline between the water inlet pump 61 and the reaction device 3, and are used for realizing one-way liquid inlet from the liquid storage device 1 to the reaction device 3. The connection or disconnection between the liquid storage device 1 and the reaction device 3 is realized through the cooperation of the water inlet pump 61 and the one-way valve 62.

When the control device 4 sends out a command and the liquid storage device 1 and the reaction device 3 need to be communicated, the water inlet pump 61 starts to work to pump water from the liquid storage device 1, liquid in the liquid storage device 1 flows along a pipeline under the pressure of the water inlet pump 61, and has certain water pumping pressure of the water inlet pump 61, the one-way valve 62 is pushed open under the action of the pressure, and the liquid storage device 1 is communicated with the reaction device 3 under the continuous work of the water inlet pump 61 and the water is fed in a one-way mode. After the liquid level sensor 11 detects that the liquid level in the reaction device 3 reaches a fixed position, the liquid level signal is fed back to the control device 4, the control device 4 controls the water inlet pump 61 to stop working, and the check valve 62 is automatically closed under the action of no liquid pressure, so that the work of injecting water from the liquid storage device 1 is completed.

In this embodiment, the setting of check valve 62 can guarantee that when pressure was too big in reaction unit 3, can not open the valve of intercommunication through pressure, avoids under the effect of the reverse force in reaction unit 3, makes stock solution device 1 and reaction unit 3 intercommunication, improves the stability that the utensil used.

As an embodiment of the present application, as shown in fig. 7, 8, 9 and 10, the soda machine further includes an air inlet mechanism 7, and the air inlet mechanism 7 is used for controlling the connection or disconnection between the air storage device 2 and the reaction device 3 under the control of the control device 4; the gas storage device 2 is provided with a gas outlet 21 and a plugging cavity 22, and the gas outlet 21 is communicated with the reaction device 3 through the plugging cavity 22; the air inlet mechanism 7 comprises a sealing part, wherein the sealing part is positioned in the plugging cavity 22 and can move in the plugging cavity 22 to plug the plugging cavity 22 or conduct the plugging cavity 22 so as to conduct or disconnect the air outlet 21 and the reaction device 3; the end part of the ejector rod 74 is matched with the sealing part to push the sealing part to move in the plugging cavity 22; an air inlet driving component which is connected with the mandril 74 and is used for driving the mandril 74 to move; the air inlet driving component comprises an air inlet driving motor 73, an air inlet pressure rod 71 and an air inlet cam 72, and the air inlet driving motor 73 is used for driving the air inlet cam 72 to rotate; the intake cam 72 and the ram 74 are respectively connected to two ends of the intake pressure lever 71, the intake pressure lever 71 can rotate around a second rotation center 76, and the ram 74 is located between the second rotation center 76 and the intake cam 72. The air inlet mechanism 7 further includes a second elastic member 78, and both ends of the second elastic member 78 respectively abut against the sealing portion and the inner wall of the blocking cavity 22. Specifically, the air inlet cam 72 is matched to rotate so as to realize the reciprocating rotation of the air inlet pressure rod 71, so that the position of the air inlet pressure rod 71 on the push rod 74 is controlled, and the push rod 74 moves relative to the sealing part. Preferably, the second rotation center 76 is fixed to the body 5, and the intake pressure lever 71 is rotatable about the second rotation center 76 with respect to the body 5. The sealing part comprises a fixing rod 77 and a sealing sheet 75 arranged on the fixing rod 77, and the sealing sheet 75 is used for sealing the end part of the sealing cavity 22. And when the sealing sheet 75 does not seal the end part of the sealing cavity 22, a gap is left between the edge of the sealing sheet 75 and the sealing cavity 22, and carbon dioxide overflowing from the gas outlet 21 enters the reaction device 3 through the gap, so that the conduction of the two is realized. In a natural state, due to the action of a second elastic component 78 (preferably a spring), the sealing sheet 75 is blocked at one end of the blocking cavity 22 far away from the air outlet 21, the fixing rod 77 penetrates through the sealing sheet 75 and extends out of the blocking cavity 22, the end of the ejector rod 74 is in contact fit with the fixing rod 77, and under the action of the ejector rod 74, the fixing rod 74 is pushed to vertically move, so that the sealing sheet 75 is conducted or sealed on the blocking cavity 22.

When the air inlet mechanism 7 works, under the control of the control device 4, the output shaft of the air inlet driving motor 73 rotates to drive the air inlet cam 72 to rotate, the air inlet pressure rod 71 is driven to rotate along with the rotation of the air inlet cam 72 to push the ejector rod 74 to move, the end part of the ejector rod 74 pushes the sealing sheet 75 open, the sealing sheet 75 is positioned in the plugging cavity 22, and a gap exists between the edge of the sealing sheet 75 and the inner wall of the plugging cavity 22, so that the air outlet 21 of the air storage device 2 is communicated with the reaction device 3 to realize inflation. After the gas is filled, under the action of the gas inlet cam 72, the ejector rod 74 moves reversely, and the sealing sheet 75 pushes the sealing sheet 75 to reset under the action of the second elastic component 78, namely, the spring, so as to block the gas outlet 21 of the gas storage device 2, thereby realizing the disconnection between the gas storage device 2 and the reaction device 3 and stopping the gas filling. Under the effect of the structure matching, the plugging is stable, the sealing stability of the plugging is ensured, the opening is convenient for inflating, and the stability is good.

As a specific embodiment of the present application, as shown in fig. 2 and 3, the present invention includes a joint part 10, the joint part 10 is provided with a first joint 101, and the first joint 101 is connected to the reaction device 3; the joint part 10 is further provided with a second joint 102, a third joint 103 and a fourth joint 104, the second joint 102 is used for communicating the liquid storage device 1 with the reaction device 3, the third joint 103 is used for communicating the gas storage device 2 with the reaction device 3, and the fourth joint 104 is used for communicating the reaction device 3 with the outside. The liquid storage device 1, the gas storage device 2, the reaction device 3, the pressure relief mechanism 8 and the like are connected together through the joint part 10. That is, the reaction apparatus 3 is communicated with the outside through the pressure relief mechanism 8 provided in the fourth joint 104, and the fourth joint 104 can be a pressure relief port 104.

Preferably, as shown in fig. 4, the gas storage device further comprises a gas needle 9, wherein the gas needle 9 penetrates through the third joint 103 and at least partially extends into the inner cavity of the reaction device 3, so as to communicate the gas storage device 2 with the reaction device 3; wherein, the tip that air needle 9 stretched into reaction unit 3 internal portion is equipped with the air cock 91 of intercommunication, and level sensor 11 arranges air needle 9 outer wall in and at least at 5mm with the distance of air cock 91 to guarantee that air needle 9 can stretch into more than 5mm of liquid level. When the temperature sensing device 12 is disposed in the reaction device 3, it may be disposed in the air needle 9 and between the liquid level sensor 11 and the air nozzle 91, so as to ensure the detection of the temperature of the liquid inside.

The invention also provides a soda water manufacturing method, which is applied to any one of the soda water machines and comprises the following steps:

s11: detecting a temperature signal of the liquid in the reaction device 3 and/or the liquid storage device 1;

s21: and judging the temperature interval of the temperature signal, and controlling the preset conduction time of the reaction device 3 and the gas storage device 2 according to the temperature interval.

Further, in step S21, when the temperature signal is below 5 ℃, controlling the preset on-time to be 2.5-3.5 seconds;

when the temperature signal is at 5-15 ℃, controlling the preset conduction time to be 2-2.5 seconds;

when the temperature signal is at 15-45 ℃, controlling the preset conduction time to be 1.5-2 seconds;

and when the temperature signal is above 45 ℃, controlling the preset conduction time within 1.5 seconds.

Further, in S21, it is further determined whether the temperature signal reaches a first critical temperature and a second critical temperature, and if so, the gas storage device 2 and the reaction device 3 are disconnected;

wherein the first critical temperature is 0 ℃ and the second critical temperature is 50 ℃.

Further, a liquid level sensor 11 is arranged inside the reaction device 3, and the liquid level sensor 11 is used for detecting a liquid level signal in the reaction device 3;

before step S11, the method further includes:

s10: and when the liquid level signal reaches a water level critical signal, the liquid storage device 1 and the reaction device 3 are controlled to be disconnected.

Further, a pressure sensor 13 is arranged in the reaction device 3, and the pressure sensor 13 is used for detecting a pressure signal in the reaction device 3;

in step S21, the method further includes:

s211: and when the pressure signal reaches a pressure critical signal, controlling the gas storage device 2 to be disconnected from the reaction device 3.

Further, in step S21, after the conduction time between the gas storage device 2 and the reaction device 3 reaches the preset conduction time, the method further includes:

s22: the gas storage device 2 is disconnected from the reaction device 3;

s23: and (3) carrying out pressure relief operation on the reaction device 3.

The soda water manufacturing method adopts the soda water machine to manufacture soda water, the effect which can be achieved is the same as that of the soda water machine, and the description is omitted.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (16)

1. A soda machine, characterized by comprising:

the liquid storage device (1), the liquid storage device (1) is used for storing liquid;

the gas storage device (2), the gas storage device (2) is used for storing carbon dioxide;

the reaction device (3) is communicated with the liquid storage device (1) and the gas storage device (2), and liquid in the liquid storage device (1) and carbon dioxide in the gas storage device (2) are mixed in the reaction device (3);

the temperature sensing device (12), the temperature sensing device (12) is used for detecting a temperature signal of the reaction device (3) and/or the liquid storage device (1);

the temperature sensing device (12) feeds the temperature signal back to the control device (4), and the control device (4) is used for controlling the conduction time of the gas storage device (2) and the reaction device (3) according to the temperature signal.

2. The soda machine according to claim 1, characterised in that said control means (4) are also adapted to control the connection or disconnection of said gas storage means (2) to said reaction means (3).

3. The soda machine according to claim 1, characterised in that a liquid level sensor (11) is arranged inside said reaction device (3), said liquid level sensor (11) being adapted to detect a liquid level signal inside said reaction device (3);

the liquid level sensor (11) feeds the liquid level signal back to the control device (4), and the control device (4) is also used for controlling the connection or disconnection between the liquid storage device (1) and the reaction device (3) according to the liquid level signal.

4. The soda machine according to claim 1, characterised in that a pressure sensor (13) is arranged in said reaction device (3), said pressure sensor (13) being adapted to detect a pressure signal in said reaction device (3);

the pressure sensor (13) feeds the pressure signal back to the control device (4), and the control device (4) is also used for controlling the connection or disconnection of the gas storage device (2) and the reaction device (3) according to the pressure signal.

5. The soda machine according to claim 1, characterised in that said temperature sensing means (12) are arranged inside said liquid storage means (1) and are NTC thermistors (121); and/or the presence of a gas in the gas,

the temperature sensing device (12) is arranged in the reaction device (3) and is a temperature sensor (122).

6. The soda machine according to any of the claims 1 to 5, characterised in that it further comprises a pressure relief mechanism (8), said pressure relief mechanism (8) being electrically connected to said control device (4);

under the control of the control device (4), the pressure relief mechanism (8) can control the reaction device (3) to be connected with or disconnected from the external environment.

7. The soda machine according to claim 6, characterised in that said reaction device (3) has a pressure relief vent (104) and an installation cavity (105), said pressure relief vent (104) being in communication with the external environment through said installation cavity (105);

the pressure relief mechanism (8) comprises a pressure relief mechanism,

the pressure relief valve comprises a pressure relief valve rod (84) and a blocking part (85), the blocking part (85) is positioned in the installation cavity (105) and can move in the installation cavity (105) to block the pressure relief opening (104) and the installation cavity (105) or conduct the pressure relief opening (104) and the installation cavity (105);

the pressure relief driving part is connected with the pressure relief valve rod (84) and is used for driving the pressure relief valve to move;

the pressure relief driving part comprises a pressure relief driving motor (83), a pressure relief pressure rod (81) and a pressure relief cam (82), and the pressure relief driving motor (83) is used for driving the pressure relief cam (82) to rotate;

the pressure relief cam (82) and the pressure relief valve rod (84) are respectively connected to two ends of the pressure relief pressure rod (81), the pressure relief pressure rod (81) can rotate around a first rotation center (87), and the pressure relief valve rod (84) is located between the first rotation center (87) and the pressure relief cam (82);

the pressure relief mechanism (8) further comprises a first elastic part (86), and two ends of the first elastic part (86) are respectively abutted against the inner wall of the mounting cavity (105) and the pressure relief valve.

8. The soda machine according to any of the claims 1 to 5, characterised in that it further comprises a water inlet means (6), said water inlet means (6) being adapted to control the connection or disconnection of said reservoir means (1) to said reaction means (3) under the control of said control means (4);

wherein the water inlet mechanism (6) comprises,

the water inlet pump (61), the water inlet pump (61) is electrically connected with the control device (4);

check valve (62), check valve (62) are arranged in intake pump (61) with communicating pipe between reaction unit (3) is on the way for realize stock solution device (1) to reaction unit (3) interior one-way feed liquor.

9. The soda machine according to any of the claims 1 to 5, characterised in that it further comprises air intake means (7), said air intake means (7) being adapted to control the connection or disconnection of said air storage means (2) to said reaction means (3) under the control of said control means (4);

the gas storage device (2) is provided with a gas outlet (21) and a plugging cavity (22), and the gas outlet (21) is communicated with the reaction device (3) through the plugging cavity (22);

wherein the air intake mechanism (7) comprises,

a sealing part which is positioned in the plugging cavity (22) and can move in the plugging cavity (22) to plug the plugging cavity (22) or conduct the plugging cavity (22) so as to conduct or disconnect the gas outlet (21) and the reaction device (3);

the end part of the ejector rod (74) is matched with the sealing part to push the sealing part to move in the plugging cavity (22);

the air inlet driving component is connected with the ejector rod (74) and is used for driving the ejector rod (74) to move;

the air inlet driving component comprises an air inlet driving motor (73), an air inlet pressure rod (71) and an air inlet cam (72), and the air inlet driving motor (73) is used for driving the air inlet cam (72) to rotate;

the air inlet cam (72) and the ejector rod (74) are respectively connected with two ends of the air inlet pressure rod (71), the air inlet pressure rod (71) can rotate around a second rotation center (76), and the ejector rod (74) is located between the second rotation center (76) and the air inlet cam (72).

The air inlet mechanism (7) further comprises a second elastic component (78), and two ends of the second elastic component (78) are respectively abutted against the sealing part and the inner wall of the blocking cavity (22).

10. The soda machine according to claim 3, comprising,

the joint part (10), the joint part (10) is provided with a first joint (101), and the first joint (101) is connected with the reaction device (3);

the joint part (10) is further provided with a second joint (102), a third joint (103) and a fourth joint (104), the second joint (102) is used for communicating the liquid storage device (1) with the reaction device (3), the third joint (103) is used for communicating the gas storage device (2) with the reaction device (3), and the fourth joint (104) is used for communicating the reaction device (3) with the outside;

the gas needle (9) penetrates through the third connector (103) and at least partially extends into the inner cavity of the reaction device (3) so as to realize the communication between the gas storage device (2) and the reaction device (3);

wherein, the liquid level sensor (11) is arranged on the outer wall of the air needle (9).

11. A soda water production method applied to the soda water machine of any one of claims 1 to 10, characterized by comprising the steps of:

s11: detecting a temperature signal of the liquid in the reaction device (3) and/or the liquid storage device (1);

s21: and judging the temperature interval where the temperature signal is positioned, and controlling the preset conduction time of the reaction device (3) and the gas storage device (2) according to the temperature interval.

12. The soda water making method according to claim 11, wherein in step S21, when the temperature signal is below 5 ℃, the preset on-time is controlled to be 2.5 to 3.5 seconds;

when the temperature signal is at 5-15 ℃, controlling the preset conduction time to be 2-2.5 seconds;

when the temperature signal is at 15-45 ℃, controlling the preset conduction time to be 1.5-2 seconds;

and when the temperature signal is above 45 ℃, controlling the preset conduction time within 1.5 seconds.

13. The soda water production method according to claim 11, wherein in S21, it is further determined whether the temperature signal reaches a first critical temperature and a second critical temperature, and if so, the gas storage device (2) and the reaction device (3) are disconnected;

wherein the first critical temperature is 0 ℃ and the second critical temperature is 50 ℃.

14. The soda water production method according to claim 11, characterized in that a liquid level sensor (11) is arranged inside the reaction device (3), and the liquid level sensor (11) is used for detecting a liquid level signal in the reaction device (3);

before step S11, the method further includes:

s10: and when the liquid level signal reaches a water level critical signal, the liquid storage device (1) and the reaction device (3) are controlled to be disconnected.

15. The soda water production method according to claim 11, characterized in that a pressure sensor (13) is arranged in the reaction device (3), and the pressure sensor (13) is used for detecting a pressure signal in the reaction device (3);

in step S21, the method further includes:

s211: and when the pressure signal reaches a pressure critical signal, the gas storage device (2) is controlled to be disconnected from the reaction device (3).

16. The method for producing carbonated water according to claim 11, wherein in step S21, after the conduction time between the gas storage device (2) and the reaction device (3) reaches the preset conduction time, the method further comprises:

s22: the gas storage device (2) is disconnected from the reaction device (3);

s23: and carrying out pressure relief operation on the reaction device (3).

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