CN219661446U - Multifunctional drinking water system - Google Patents

Abstract

The utility model relates to the technical field of drinking water equipment, in particular to a multifunctional drinking water system, which comprises a carbonic acid tank, wherein a normal-temperature water inlet and a carbon dioxide inlet are arranged at the carbonic acid tank; the carbon dioxide gas tank is connected with the carbon dioxide inlet; one end of the bubble water outlet is connected with the carbonic acid tank, and the other end of the bubble water outlet is connected with a water outlet of the drinking water device; according to the utility model, the carbon dioxide gas tank can be opened according to the requirement, so that carbon dioxide is filled into the carbonic acid tank, and the carbon dioxide is combined with normal-temperature water in the carbonic acid tank to form bubble water.

Description

Multifunctional drinking water system

Technical Field

The utility model relates to the technical field of drinking equipment, in particular to a multifunctional drinking system.

Background

In most commercial or domestic direct drinking machines, water bar machines and coffee machine equipment in the current market, it is common to purify tap water to obtain potable purified water.

With the progress of human beings, more and more people pursue healthy beverages, so that bubble water mainly playing the concepts of sugar-free and healthy starts to become a market place.

In view of the above, a multifunctional drinking water system is proposed, which can meet the requirement of consumers on bubble water by installing a device capable of making bubble water on a direct drinking machine, a water bar machine or a coffee machine device.

Disclosure of Invention

The present utility model provides a multi-functional drinking water system, which aims at the problems existing in the prior art.

In order to solve the technical problems, the utility model is solved by the following technical scheme:

a multifunctional drinking water system, which comprises a water tank, which comprises the steps of (a) a step of,

a carbonic acid tank, wherein a normal-temperature water inlet and a carbon dioxide inlet are arranged at the carbonic acid tank;

the carbon dioxide gas tank is connected with the carbon dioxide inlet;

and one end of the bubble water outlet is connected with the carbonic acid tank, and the other end of the bubble water outlet is connected with a water outlet of the drinking water device.

Preferably, the system also comprises a refrigeration coil, a compressor and a condenser,

the refrigerating coil is arranged in the carbonic acid tank;

the inlet end of the compressor is connected with the outlet end of the refrigeration coil;

the inlet end of the condenser is connected with the outlet end of the compressor, and the outlet end of the condenser is connected with the inlet end of the refrigeration coil.

Preferably, the water-cooling device also comprises an ice water pipeline and a water pump,

the ice water pipeline is arranged in the carbonic acid tank;

the inlet end of the water pump is connected with the outlet end of the ice water pipeline, and the outlet end of the water pump is connected with the inlet end of the ice water pipeline.

Preferably, the carbon dioxide inlet is connected with the carbonic acid tank and the ice water pipeline respectively.

Preferably, the carbonic acid tank is provided with an air pressure sensor through a first interface.

Preferably, the carbonic acid tank is provided with a safety valve through a second interface.

Preferably, the water level probe comprises a water level probe port and a binding post;

the water level probe opening is arranged at the carbonic acid tank and is used for installing a water level probe;

one end of the binding post extends into the carbonic acid tank and is connected with the water level probe, and the other end of the binding post is positioned outside the carbonic acid tank and is connected with a ground wire.

Preferably, the carbonic acid tank is provided with a temperature probe with one end extending into the carbonic acid tank through a temperature probe opening.

The utility model has at least the following beneficial effects:

1. the carbon dioxide gas tank can be opened according to the requirement, so that carbon dioxide is filled into the carbonic acid tank, and the carbon dioxide is combined with normal-temperature water in the carbonic acid tank to form bubble water.

2. Through carrying in carrying the carbonic acid jar with the air after compressing and cooling treatment, can further realize carrying out cooling treatment to normal atmospheric temperature water to can make and provide cold water for the user preferably, combine the injection of carbon dioxide simultaneously can make cold drink bubble water preferably.

3. Through the real-time monitoring and the feedback of the air pressure sensor, the filling amount of the carbon dioxide can be controlled better, so that the safety is improved.

4. Under the condition that too much carbon dioxide is filled in the carbonic acid tank, the carbon dioxide in the carbonic acid tank can be discharged by opening the safety valve, so that the air pressure in the carbonic acid tank is reduced, and the safety is improved.

Drawings

FIG. 1 is a schematic diagram of a multi-purpose drinking water system of the present utility model;

FIG. 2 is a schematic diagram of a carbonic acid tank in the present utility model.

The names of the parts indicated by the numerical references in the drawings are as follows:

110. a carbonic acid tank; 120. a refrigeration coil; 130. a compressor; 140. a condenser; 150. ice water pipeline; 160. a water pump; 210. a normal temperature water inlet; 220. a carbon dioxide inlet; 230. a bubble water outlet; 240. a first interface; 250. a second interface; 260. a water level probe port; 261. binding posts; 270. a temperature probe port.

Detailed Description

For a further understanding of the present utility model, the present utility model will be described in detail with reference to the drawings and examples. It is to be understood that the examples are illustrative of the present utility model and are not intended to be limiting.

As shown in fig. 1-2, the present embodiment provides a multi-functional drinking water system, which includes,

a carbonic acid tank 110, wherein a normal temperature water inlet 210 and a carbon dioxide inlet 220 are arranged at the carbonic acid tank 110;

a carbon dioxide tank connected to the carbon dioxide inlet 220;

and a bubble water outlet 230, one end of which is connected with the carbonic acid tank 110, and the other end of which is connected with the water outlet of the drinking water apparatus.

In this embodiment, a carbonic acid tank 110 and a carbon dioxide tank are additionally installed at the drinking device, normal temperature water filtered by the drinking device flows into the carbonic acid tank 110 through a normal temperature water inlet 210 through a connecting pipeline, and the carbon dioxide tank is connected with a carbon dioxide inlet 220 through a pipeline;

when in use, the carbon dioxide gas tank can be opened according to the requirement, so that carbon dioxide is filled into the carbonic acid tank 110, and then the carbon dioxide is combined with the normal-temperature water in the carbonic acid tank 110 to form bubble water;

it is understood that the carbon dioxide tank may be opened or closed manually, or may be opened or closed automatically by means of electrical control, so as to provide the user with water of bubbles.

In this embodiment, a refrigeration coil 120, a compressor 130 and a condenser 140 are also included,

the refrigeration coil 120 is arranged in the carbonic acid tank 110;

an inlet end of the compressor 130 is connected to an outlet end of the refrigeration coil 120;

the inlet end of the condenser 140 is connected to the outlet end of the compressor 130, and the outlet end of the condenser 140 is connected to the inlet end of the refrigeration coil 120.

Through the arrangement of the refrigeration coil 120, the compressor 130 and the condenser 140 in the embodiment, after the compressor 130 and the condenser 140 are started, the compressor 130 compresses air and then conveys the compressed air into the condenser 140 for cooling treatment, so that the air conveyed into the refrigeration coil 120 from the condenser 140 has lower temperature, and the low-temperature air in the refrigeration coil 120 can exchange heat with normal-temperature water in the carbonic acid tank 110, thereby reducing the temperature of the low-temperature water, and the temperature of the air after heat exchange rises and flows to the compressor 130 again to realize circulation;

it should be noted that, by compressing air and cooling it, delivering it into the carbonic acid tank 110, cooling it can be further realized, so that cold water can be preferably produced and provided for users, and cold water and bubble water can be preferably produced by combining carbon dioxide injection.

In this embodiment, the ice water pipe 150 and the water pump 160 are further included,

the ice water pipe 150 is provided in the carbonic acid tank 110;

an inlet end of the water pump 160 is connected with an outlet end of the ice water pipe 150, and an outlet end of the water pump 160 is connected with an inlet end of the ice water pipe 150.

Through the structure in the embodiment, the ice water pipeline 150 is independently arranged in the carbonic acid tank 110, and the external ice water can be preferably conveyed into the carbonic acid tank 110 through the external water pump 160, in the embodiment, the ice water outlet connected with the ice water pipeline 150 is further arranged at the outlet of the carbonic acid tank 110, so that the ice water is provided for a user;

it can be appreciated that the ice water can be timely conveyed into the carbonic acid tank 110 through the conveying of the water pump 160, so that the working efficiency is improved, meanwhile, the ice water in the ice water pipeline 150 is pumped out through the water pump 160, and the ice water outlet is opened while the ice water is pumped out, so that the ice water can be better provided for users.

In this embodiment, the carbon dioxide inlet 220 is connected to the carbonate tank 110 and the iced water pipe 150, respectively.

In this embodiment, a first valve is disposed at the communication position between the carbon dioxide inlet 220 and the carbonic acid tank 110; a second valve is arranged at the joint of the carbon dioxide inlet 220 and the ice water pipeline 150;

when in use, the first valve is opened, so that carbon dioxide can be filled into the carbonic acid tank 110 and combined with normal-temperature water; the second valve is opened, so that carbon dioxide can be filled into the ice water pipeline 150 and combined with ice water, and ice beverage bubble water is provided for a user, so that different requirements of the user can be met;

it should be noted that, in this embodiment, the first valve and the second valve may be a check valve or other structures capable of preventing water from flowing into the carbon dioxide tank.

In this embodiment, the carbonic acid tank 110 is provided with a gas pressure sensor through the first interface 240.

In this embodiment, the first interface 240 is fixedly connected with an air pressure sensor with one end extending into the carbonic acid tank 110 through threads, and the air pressure in the carbonic acid tank 110 is monitored in real time through the air pressure sensor, so that the excessive air pressure in the carbonic acid tank 110 caused by excessive carbon dioxide filling is avoided;

it can be appreciated that the amount of carbon dioxide charged can be preferably controlled by real-time monitoring and feedback of the air pressure sensor to improve safety.

In this embodiment, a safety valve is provided at the carbonic acid tank 110 through the second port 250.

By the configuration in this embodiment, the second port 250 is fixedly connected with the safety valve through the screw thread, and in the case of filling too much carbon dioxide into the carbonic acid tank 110, the carbon dioxide in the carbonic acid tank 110 can be discharged by opening the safety valve, thereby reducing the air pressure in the carbonic acid tank 110 and improving the safety.

In this embodiment, the water level probe port 260 and the binding post 261 are further included;

the water level probe port 260 is provided at the carbonic acid tank 110 and is used for installing a water level probe;

one end of the binding post 261 extends into the carbonic acid tank 110 and is connected with the water level probe, and the other end is located outside the carbonic acid tank 110 and is connected with a ground wire.

Through the construction in the embodiment, the water level probe port 260 is fixedly connected with a water level probe with one end extending into the carbonic acid tank 110 through threads, so that the water level in the carbonic acid tank 110 is monitored, and when the normal-temperature water in the carbonic acid tank 110 is about to be used up, the normal-temperature water can be timely replenished;

the water level probe is connected with the ground wire through the binding post 261, so that the safe use of the water level probe can be better ensured.

In this embodiment, a temperature probe having one end extending into the carbonic acid tank 110 is provided at the carbonic acid tank 110 through a temperature probe port 270.

Through the setting of the temperature probe in this embodiment, the water temperature in the carbonic acid tank 110 can be monitored preferably, so that the water temperature in the carbonic acid tank 110 can be adjusted preferably, and the bubble water with the corresponding temperature is provided for the user.

In summary, the foregoing description is only of the preferred embodiments of the present utility model, and all equivalent changes and modifications made in accordance with the claims should be construed to fall within the scope of the utility model.

Claims (6)

1. A multi-functional drinking water system, characterized in that: comprising the steps of (a) a step of,

a carbonic acid tank, wherein a normal-temperature water inlet and a carbon dioxide inlet are arranged at the carbonic acid tank;

the carbon dioxide gas tank is connected with the carbon dioxide inlet;

one end of the bubble water outlet is connected with the carbonic acid tank, and the other end of the bubble water outlet is connected with a water outlet of the drinking water device;

also comprises a refrigeration coil, a compressor and a condenser,

the refrigerating coil is arranged in the carbonic acid tank;

the inlet end of the compressor is connected with the outlet end of the refrigeration coil;

the inlet end of the condenser is connected with the outlet end of the compressor, and the outlet end of the condenser is connected with the inlet end of the refrigeration coil;

also comprises an ice water pipeline and a water pump,

the ice water pipeline is arranged in the carbonic acid tank;

the inlet end of the water pump is connected with the outlet end of the ice water pipeline, and the outlet end of the water pump is connected with the inlet end of the ice water pipeline.

2. A multi-purpose drinking water system as set forth in claim 1 wherein: the carbon dioxide inlet is respectively connected with the carbonic acid tank and the ice water pipeline.

3. A multi-purpose drinking water system as set forth in claim 1 wherein: the carbonic acid tank is provided with an air pressure sensor through a first interface.

4. A multi-purpose drinking water system according to claim 1 or 3, wherein: and a safety valve is arranged at the carbonic acid tank through a second interface.

5. A multi-purpose drinking water system as set forth in claim 1 wherein: the water level probe comprises a water level probe opening and a binding post;

the water level probe opening is arranged at the carbonic acid tank and is used for installing a water level probe;

one end of the binding post extends into the carbonic acid tank and is connected with the water level probe, and the other end of the binding post is positioned outside the carbonic acid tank and is connected with a ground wire.

6. A multi-purpose drinking water system as set forth in claim 1 wherein: the carbonic acid tank is provided with a temperature probe with one end extending into the carbonic acid tank through a temperature probe opening.