CN219701599U - Microbubble continuous generation device and water supply system - Google Patents

Abstract

The utility model discloses a microbubble continuous generation device and a water supply system, comprising: the micro bubble tank is two in number and comprises a tank body, an excitation piece and an elastic piece, wherein the tank body is provided with a dissolving cavity, a water inlet, a water outlet and a water discharge hole, the water inlet, the water outlet and the water discharge hole are communicated with the dissolving cavity, the excitation piece is located in the tank body and divides the dissolving cavity into a first cavity and a second cavity, the excitation piece is located in the tank body and divides the dissolving cavity into the first cavity and the second cavity, the first cavity is communicated with the water inlet, the second cavity is communicated with the water outlet and the water discharge hole, the excitation piece is provided with an injection hole communicated with the first cavity and the second cavity and comprises a sealing part arranged towards the water discharge hole, the sealing part can move between a working position and an initial position, and the working position and the initial position are sequentially arranged along the direction from the first cavity to the second cavity. The continuous generation device of the micro-bubbles can continuously generate the micro-bubble water, and an air pump is not needed to be used as a power source for ventilation, so that the manufacturing cost is low.

Description

Microbubble continuous generation device and water supply system

Technical Field

The utility model relates to the technical field of microbubbles, in particular to a microbubble continuous generation device.

Background

The micro-nano bubbles are abbreviated as micro-bubbles, and refer to bubbles with the diameter smaller than 100 micrometers in liquid, and are generated when bubbles are generated in water by a micro-bubble generating device through a physical principle. Microbubbles have significant uses for our life, such as cleaning fruits and vegetables with a microbubble faucet, and can effectively remove most pesticide residues; the microbubble shower head is used for bathing, can deeply clean skin, fine and smooth and remove turbid urine, and can effectively replace the use of chemical bath lotion.

In the related art, the micro-bubble generating device fully contacts air and water in a single tank body to form micro-bubble water, and after a period of operation, the micro-bubble generating device needs to stop working and supplement air into the tank body as the air in the tank body is consumed, so that the micro-bubble water can be continuously generated, namely the micro-bubble generating device of the single tank body cannot continuously generate the micro-bubble water.

In order to realize continuous output of the micro bubble water, the existing micro bubble generating device works alternately through two tanks, namely when the micro bubble water is generated in the first tank, the second tank pauses to generate the micro bubble water and supplements air, after a period of time, the first tank pauses to generate the micro bubble water and supplements air, and the second tank takes over to generate the micro bubble water, so that the micro bubble water is circularly generated. Wherein, this microbubble generating device needs to supply air for the jar body that pauses through the air pump.

It can be seen that the existing microbubble generating device has the following technical problems: the micro-bubble generating device cannot continuously generate micro-bubble water; or the microbubble generating device can continuously generate the microbubble water, but the air pump is needed to supplement air for the tank body, so that the manufacturing cost is high.

Disclosure of Invention

(one) solving the technical problems

The utility model provides a continuous generation device of micro-bubbles, which solves the technical problems that: how to continuously generate the micro-bubble water and reduce the manufacturing cost of the micro-bubble generating device.

(II) technical scheme

In order to solve the technical problems, the utility model provides the following technical scheme:

a microbubble sustained generation device comprising:

two microbubble jars, the microbubble jar is used for forming the rivers into the microbubble water to set up the ventilation hole that can open and shut:

the water flow switching device is used for controlling water flow to alternately enter the two micro-bubble tanks;

the ventilation hole of the micro-bubble tank is closed when water flow enters the micro-bubble tank, and is opened when water flow stops entering the micro-bubble tank.

In a further provided aspect, the micro bubble tank includes:

the tank body is provided with a dissolved air cavity, a water inlet, a water outlet and a water drain hole, wherein the water inlet, the water outlet and the water drain hole are communicated with the dissolved air cavity, and the water drain hole is configured as the ventilation hole;

the excitation piece is positioned in the tank body and divides the dissolved air cavity into a first cavity and a second cavity, the first cavity is communicated with the water inlet, the second cavity is communicated with the water outlet and the water discharge hole, the excitation piece is provided with an injection hole communicated with the first cavity and the second cavity and comprises a sealing part arranged towards the water discharge hole, the sealing part can move between a working position and an initial position, the working position and the initial position are sequentially arranged along the direction from the first cavity to the second cavity,

an elastic member disposed between the energizing member and the can, and configured to provide a force with which the sealing portion moves toward an initial position;

wherein, in the initial position, the water discharge hole is communicated with the outside of the tank body and the dissolved air cavity; in the working position, the sealing part resists the acting force of the elastic piece through the water pressure of the first chamber and seals the water discharge hole.

In some embodiments, the device further comprises a water outlet communicating piece, wherein the water outlet communicating piece is connected with the micro-bubble tank and is provided with a converging hole communicated with water outlets of the two tank bodies.

In some embodiments, a check valve is disposed within the water outlet and configured to prevent water flow from the water outlet into the tank.

In some embodiments, the water flow switching device comprises a switching valve configured to control the water flow to alternate into the two microbubble tanks in the operating state of the microbubble continuous generation device.

In some embodiments, the operating state comprises a switching state in which the switching valve controls water flow into both of the microbubble tanks simultaneously.

In some embodiments, the water flow switching device further comprises a water flow sensing unit, a control unit and a power supply unit, wherein the water flow sensing unit is used for sensing water flow and feeding back sensing signals to the control unit, the switching valve is an electric switching valve, the control unit is used for controlling the electric switching valve to work, and the power supply unit is used for supplying power to the water flow sensing unit, the control unit and the electric switching valve.

In some embodiments, the sealing part comprises a shaft section, the elastic piece is a pressure spring, the pressure spring is sleeved on the shaft section, and two ends of the pressure spring respectively lean against the sealing part and the tank body.

In some embodiments, the tank comprises a container lid and a sealing lid, the two tanks are connected by the same container lid, and the sealing lid is arranged on the container lid.

The utility model also provides a water supply system which comprises a water terminal and the micro-bubble continuous generation device, wherein the water terminal is communicated with a water outlet of the micro-bubble continuous generation device.

In some embodiments, the microbubble continuous generation device further comprises a water outlet communicating piece, wherein the water outlet communicating piece is connected with the microbubble tank and is provided with a confluence hole communicated with water outlets of the two microbubble tanks, and the water terminal is communicated with the water outlets through the confluence hole.

(III) beneficial effects

Compared with the prior art, the continuous generation device of the micro-bubbles provided by the utility model has the following beneficial effects:

when the microbubble continuous generation device works, the water flow switching device controls water flow to alternately enter the two microbubble tanks, the microbubble tanks treat the water flow into microbubble water, wherein the ventilation holes of the microbubble tanks are closed when the water flow enters the microbubble tanks, so that the microbubble tanks can treat the water flow into the microbubble water without influencing the output of the microbubble water, the ventilation holes of the microbubble tanks are opened when the water flow stops entering the microbubble tanks, and air enters the microbubble tanks from the ventilation holes to supplement air to the microbubble tanks. Therefore, the micro-bubble continuous generation device can continuously generate micro-bubble water, an air pump is not needed to be used as a power source for ventilation, and the manufacturing cost is low.

Compared with the prior art, the scheme provided by the utility model has the following beneficial effects:

before the microbubble continuous generation device works, the excitation parts of the two microbubble tanks are positioned at the initial positions, and the water discharge holes are opened; when the water flow switching device works, water flow is firstly controlled to enter a first tank body, after the water flow enters a first cavity from a water inlet of the tank body, the sealing part is pushed by water pressure to resist the acting force of the elastic piece, the sealing part moves to a working position from an initial position before working, a water discharge hole is sealed by the sealing part, and meanwhile, the water flow enters a second cavity from the first cavity through an injection hole and fully contacts with air in the second cavity to form micro-bubble water, and the micro-bubble water flows out from a water outlet; when the first micro-bubble tank works for a period of time and air in the tank body is consumed, the water flow switching device controls water flow to enter the second tank body, the sealing part of the excitation piece in the first tank body is reset to the initial position under the action of the elastic piece due to the loss of water pressure, the water discharge hole of the excitation piece in the first tank body is opened, the residual water flow in the first tank body can flow out of the water discharge hole, and meanwhile, the air can automatically enter the tank body through the water discharge hole without being driven by an air pump; the second micro-bubble tank takes over the micro-bubble water generated in the same way after the water flow enters the tank body, and also ventilates after working for a period of time; therefore, the microbubble continuous generation device controls water flow to alternately enter the two microbubble tanks through the water flow switching device, and the two microbubble tanks can alternately and continuously generate microbubble water. The micro-bubble continuous generation device can continuously generate micro-bubble water, and an air pump is not needed to be used as a power source for ventilation, so that the manufacturing cost is low.

Drawings

FIG. 1 is a cross-sectional view of a microbubble tank in an embodiment;

FIG. 2 is an exploded view of the microbubble tank in an embodiment;

fig. 3 is a schematic diagram of a microbubble continuous generation device and a water supply terminal in an embodiment.

Reference numerals: the micro bubble tank 1, the water flow switching device 2, the water outlet communicating member 3, the check valve 4, the water use terminal 5, the tank body 11, the exciting member 12, the elastic member 13, the switching valve 21, the water flow sensing unit 22, the control unit 23, the power supply unit 24, the confluence hole 30, the first chamber 101, the second chamber 102, the dissolved air chamber 110, the water inlet 111, the water outlet 112, the water drain hole 113, the container cover 114, the sealing cover 115, the injection hole 120, and the sealing part 121.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

In the related art, the microbubble generating device has the following technical problems: the micro-bubble generating device of the single tank body cannot continuously generate micro-bubble water; the micro-bubble generating device with double tank bodies can continuously generate micro-bubble water, but the tank bodies need to be supplemented with air through the air pump, so that the manufacturing cost is high.

Referring to fig. 1, 2 and 3, fig. 1 is a cross-sectional view of a microbubble tank in an embodiment, fig. 2 is an exploded view of the microbubble tank in an embodiment, and fig. 3 is a schematic view of a microbubble sustained generation device and a water supply terminal in an embodiment.

To solve the above technical problem, this embodiment provides a microbubble continuous generation device, including: a micro bubble tank 1 and a water flow switching device 2.

The number of the micro bubble tanks 1 can be two, at least one group is arranged, and the micro bubble tanks 1 are used for generating micro bubbles and are provided with ventilation holes which can be opened and closed.

And the water flow switching device 2 is used for controlling water flow to alternately enter the two micro bubble tanks 1.

Wherein the ventilation hole of the micro bubble tank 1 is closed when water flow enters the micro bubble tank, and is opened when water flow stops entering the micro bubble tank.

When the microbubble continuous generation device of the technical scheme works, the water flow switching device 2 controls water flow to alternately enter the two microbubble tanks 1, the microbubble tanks 1 process the water flow into microbubble water, wherein the ventilation holes of the microbubble tanks 1 are closed when the water flow enters the microbubble tanks, so that the microbubble tanks 1 can process the water flow into the microbubble water, the ventilation holes of the microbubble tanks 1 are opened when the water flow stops entering the microbubble tanks, and air enters the microbubble tanks 1 from the ventilation holes to supplement air to the microbubble tanks 1. Therefore, the micro-bubble continuous generation device can continuously generate micro-bubble water, an air pump is not needed to be used as a power source for ventilation, and the manufacturing cost is low.

In a further provided aspect, the micro bubble tank includes: the microbubble tank 1 includes: a tank 11, an energizing member 12 and an elastic member 13.

The tank 11 is provided with a dissolving cavity 110, a water inlet 111 communicated with the dissolving cavity 110, a water outlet 112 and a water drain hole 113.

The tank 11 is used as a container for generating micro bubble water, and is internally provided with a dissolved air cavity 110 for contacting water flow and air; wherein, the water inlet 111 is used for introducing external water flow, the water outlet 112 is used for outputting micro-bubble water to the water terminal 5 such as a shower head or a water tap, and the water outlet 113 is used for discharging the residual water flow in the tank 11 outwards and enabling external air to enter the dissolved air cavity 110. It can be understood that the tank bodies 11 can be separately arranged or integrally formed, and when the tank bodies 11 are integrally formed, two dissolved air cavities 110 are formed in one micro-bubble container.

The excitation member 12 is positioned in the tank 11 and divides the solution cavity 110 into a first cavity 101 and a second cavity 102, the first cavity 101 is communicated with the water inlet 111, the second cavity 102 is communicated with the water outlet 112 and the water drain hole 113, the excitation member 12 is provided with an injection hole 120 communicated with the first cavity 101 and the second cavity 102 and comprises a sealing part 121 arranged towards the water drain hole 113, the sealing part 121 can move between a working position and an initial position, and the working position and the initial position are sequentially arranged along the direction from the first cavity 101 to the second cavity 102.

The exciting member 12 is used for exciting the water flow to fully contact with the air to generate micro bubble water and controlling the opening and closing of the water discharge hole 113; the sealing part 121 may be integrally formed on the exciting member 12, and after the water flow enters the first chamber 101, the exciting member 12 moves towards the second chamber 102 under the action of water pressure, so as to drive the sealing part 121 to move from the initial position to the working position; of course, the sealing portion 121 may be movably disposed relative to the main body of the exciting member 12, for example, movably penetrating the main body of the exciting member 12, the main body of the exciting member 12 may be fixed relative to the tank 11, and after the water flow enters the first chamber 101, the sealing portion 121 moves independently to the working position under the action of water pressure; the jet hole 120 is used for exciting water flow, and when the water flow in the first chamber 101 enters the second chamber 102 from the jet hole 120, water drops or water spray shapes are formed, so that the contact area between the water flow and air is increased, and the water flow and the air are fully contacted to form micro-bubble water.

The elastic member 13 is disposed between the energizing member 12 and the can 11, and is configured to provide a force for moving the sealing portion 121 toward the initial position.

The elastic member 13 is used for restoring the sealing portion 121 to an initial position, wherein the elastic member 13 generates a restoring force by elastic deformation.

Suitably, the water flow switching device 2 is used for controlling water flow to alternately enter the water inlets 111 of the two tanks 11.

The water flow switching device 2 may be a switching valve or a water supply device capable of distributing water flow, etc., which is connected between the water inlet 111 and the water source to control the flow direction of the water flow.

Referring to fig. 1, in the drawing, the microbubble tank 1 on the left is in an initial state, the sealing part 121 of the excitation member 12 is in an initial position, and the sealing part 121 of the microbubble tank 1 on the right is in a working position, wherein in the initial position, the water drain hole 113 is communicated with the outside of the tank 11 and the dissolved air cavity 110; in the working position, the sealing portion 121 opposes the urging force of the elastic member 13 by the water pressure of the first chamber 101 and seals the drain hole 113.

Before the microbubble continuous generation device in the technical scheme works, the excitation parts 12 of the two microbubble tanks 1 are at the initial positions, and the water discharge holes 113 are opened; when the water flow switching device 2 is operated, firstly, water flow is controlled to enter the first right tank body 11, after entering the first cavity 101 from the water inlet 111 of the tank body 11, the water flow pushes the sealing part 121 to resist the acting force of the elastic piece 13 through water pressure, and the sealing part 121 moves to the working position from the initial position, at the moment, the water discharge hole 113 is sealed, meanwhile, water flow enters the second cavity 102 from the first cavity 101 through the injection hole 120 in the tank body 11 and fully contacts with air in the second cavity 102 to form micro-bubble water, and the micro-bubble water flows out from the water outlet 112 and is conveyed to the water terminal 5; when the first micro-bubble tank 1 works for a period of time and air in the tank body 11 is consumed, the water flow switching device 2 controls water flow to enter the left second tank body 11, the sealing part 121 of the exciting piece 12 in the right first tank body 11 loses water pressure and is reset to an initial position under the action of the elastic piece 13, the water discharge hole 113 of the sealing part is opened, the residual water flow in the right first tank body 11 can flow out from the water discharge hole 113, and meanwhile, the air can enter the right first tank body 11 through the water discharge hole 113 to realize air supplement; the second microbubble tank 1 takes over the generation of microbubble water in the same way after the water flow enters the tank 11 and also ventilates after a period of time of operation; in this way, the microbubble continuous generation device controls water flow to alternately enter the two microbubble tanks 1 through the water flow switching device 2, and the two microbubble tanks 1 can alternately and continuously generate microbubble water. It can be seen that the microbubble continuous generation device of this embodiment can continuously produce the microbubble water, and need not the air pump as the power supply of taking a breath, and the cost of manufacture is lower.

Referring to fig. 1 and 2, in order to facilitate the transportation of the generated micro bubble water from the two micro bubble tanks 1 to the water terminal 5, the micro bubble continuous generation device further includes a water outlet communicating member 3, wherein the water outlet communicating member 3 is connected with the tank bodies 11 of the micro bubble tanks 1 by means of threaded connection or snap connection, and is provided with a confluence hole 30 communicating with the water outlets 112 of the two tank bodies 11, and the confluence hole 30 is communicated with the water terminal 5. In this way, the microbubble water generated by the two microbubble tanks 1 enters the sink hole 30 through the water outlet 112, and is transported to the water terminal 5 through the sink hole 30. Of course, the water outlets 112 of the two micro bubble tanks 1 may also be respectively communicated with the water terminal 5 through water pipes, and the micro bubble water may be delivered to the water terminal 5 through the water pipes.

Wherein, the bottom ends of two jar bodies 11 can be connected through play water communication piece 3, and the top can be connected through container lid 114, so form integrative structure, jar body 11 can also seal lid 115 realization sealed on container lid 114.

Referring to fig. 1, in order to prevent water flow in one tank 11 from entering the other tank 11 through the sink hole 30, the microbubble sustained generation device further includes a check valve 4, the check valve 4 being disposed in the water outlet 112 and configured to prevent water flow from the water outlet 112 into the tank 11. In this way, the water outlet 112 can only output the water flow in the tank 11 through the action of the check valve 4, and the water flow discharged by the other tank 11 cannot be input, so that the water flows of the two tanks 11 are prevented from flowing in cross.

Referring to fig. 1 and 2, in one embodiment of the elastic member 13, the sealing portion 121 includes a shaft section 122, the elastic member 13 is a compression spring, the compression spring is sleeved on the shaft section 122, and two ends of the compression spring respectively abut against the sealing portion 121 and the tank 11.

Referring to fig. 3, in one embodiment of the water flow switching device 2, the water flow switching device 2 includes a switching valve 21, and the switching valve 21 is configured to control water flow to alternately enter the two tanks 11 in a state where the micro-bubble continuous generation device is operated. The operating state includes a switching state, in which the switching valve 21 controls water flow into the two tanks 11 simultaneously. In this embodiment, when the switching valve 21 switches the flow direction of water, there is a period of time when the two micro-bubble tanks 1 are simultaneously operated, so as to ensure stable water supply to the water terminal 5, for example, when the first micro-bubble tank 1 is switched to the second micro-bubble tank 1, the operation state is changed to: the first micro bubble tank 1 is discharged water, two micro bubble tanks 1 are discharged water simultaneously, and the second micro bubble tank 1 is discharged water.

In one control manner of the water flow switching device 2 for switching water flow, the water flow switching device 2 further comprises a water flow sensing unit 22, a control unit 23 and a power supply unit 24, wherein the water flow sensing unit 22 can be a water flow sensor for sensing water flow and feeding back a sensing signal to the control unit 23; the switching valve 21 is an electric switching valve; the control unit 23 may be a single-chip microcomputer or a controller, and is used for controlling the electric switching valve 21 to work; the power supply unit 24 may be a battery for supplying power to the water flow sensing unit 22, the control unit 23 and the electric switching valve 21. In this control mode, the water flow sensing unit 22 senses water flow and feeds back a sensing signal to the control unit 23, the control unit 23 is started, and controls the two electric switching valves 21 to alternately circulate water flow into the two tanks 11, so that the water flow continuously forms micro-bubble water for continuous use by the water terminal 5.

Referring to fig. 3, the present embodiment provides a water supply system, which includes a water terminal 5 and the microbubble continuous generation device, where the water terminal 5 is communicated with a water outlet 112 of the microbubble continuous generation device.

Further, the microbubble continuous generation device further comprises a water outlet communicating piece 3, wherein the water outlet communicating piece 3 is connected with the microbubble tank 1 and is provided with a converging hole 30 communicated with the water outlets 112 of the two tank bodies 11, and the water terminal 5 is communicated with the water outlets 112 through being communicated with the converging hole 30.

The water-using terminal 5 may be a faucet, a shower, or the like, which outputs micro-bubble water.

The water supply system of the technical scheme can continuously generate micro-bubble water through the application of the micro-bubble continuous generation device and output the micro-bubble water through the water use terminal 5.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. A microbubble sustained generation device, characterized by comprising:

two microbubble jars, the microbubble jar is used for forming the rivers into the microbubble water to set up the ventilation hole that can open and shut:

the water flow switching device is used for controlling water flow to alternately enter the two micro-bubble tanks;

the air vent of the micro-bubble tank is closed when water flow enters the micro-bubble tank, and is opened when water flow stops entering the micro-bubble tank;

the micro bubble tank includes:

the tank body is provided with a dissolved air cavity, a water inlet, a water outlet and a water drain hole, wherein the water inlet, the water outlet and the water drain hole are communicated with the dissolved air cavity, and the water drain hole is configured as the ventilation hole;

the excitation piece is positioned in the tank body and divides the dissolved air cavity into a first cavity and a second cavity, the first cavity is communicated with the water inlet, the second cavity is communicated with the water outlet and the water discharge hole, the excitation piece is provided with an injection hole communicated with the first cavity and the second cavity and comprises a sealing part arranged towards the water discharge hole, the sealing part can move between a working position and an initial position, the working position and the initial position are sequentially arranged along the direction from the first cavity to the second cavity,

an elastic member disposed between the energizing member and the can, and configured to provide a force with which the sealing portion moves toward an initial position;

wherein, in the initial position, the water discharge hole is communicated with the outside of the tank body and the dissolved air cavity; in the working position, the sealing part resists the acting force of the elastic piece through the water pressure of the first chamber and seals the water discharge hole.

2. The microbubble sustained generation device as defined in claim 1, further comprising a water outlet communicating member connected to the microbubble tank and provided with a confluence hole communicating water outlets of both the tank bodies.

3. The microbubble sustained generation device of claim 1 or 2, further comprising a check valve disposed within the water outlet configured to prevent water flow from the water outlet into the canister.

4. The microbubble sustained generation device of claim 1, wherein the water flow switching device comprises a switching valve configured to control water flow alternately into two of the microbubble tanks in an operational state of the microbubble sustained generation device.

5. The microbubble sustained release apparatus of claim 4, wherein the operating state comprises a switching state in which the switching valve controls water flow into both of the microbubble tanks simultaneously.

6. The microbubble sustained generation device as defined in claim 4 or 5, further comprising a control unit and a power supply unit, wherein the switching valve is an electric switching valve, the control unit is used for controlling the electric switching valve to work, and the power supply unit is used for supplying power to the control unit and the electric switching valve.

7. The microbubble sustained generation device according to claim 1, wherein the sealing portion comprises a shaft section, the elastic component is a compression spring, the compression spring is sleeved on the shaft section, and two ends of the compression spring respectively abut against the sealing portion and the tank body.

8. A water supply system comprising a water terminal, characterized by further comprising the microbubble continuous generation device of any one of claims 1 to 7, the water terminal being in communication with a water outlet of the microbubble continuous generation device.

9. The water supply system according to claim 8, wherein the microbubble continuous generation device further comprises a water outlet communicating member connected to the microbubble tank and provided with a confluence hole communicating with the water outlets of the two microbubble tanks, and the water terminal communicates with the water outlets by communicating with the confluence hole.