CN113578125A - Micro-nano bubble water generating device and control method thereof - Google Patents

Abstract

The invention provides a micro-nano bubble water generating device and a control method thereof, and the micro-nano bubble water generating device comprises a shell, a rotary cutting structure, a water distribution pipe and a baffle plate, wherein a cavity is formed in the shell, a water inlet, an air inlet and a water outlet are arranged on the shell, the baffle plate is arranged at one end close to the water outlet, the water inlet end of the water distribution pipe faces towards the water inlet, the water outlet end of the water distribution pipe is communicated with a first water outlet hole arranged on the baffle plate, a control valve is also arranged at the water outlet end of the water distribution pipe, the rotary cutting structure is rotatably arranged outside the water distribution pipe, a second water outlet hole is also arranged on the baffle plate, the second water outlet hole is communicated with the cavity, and the water inlet and the air inlet are communicated with the water outlet through the first water outlet hole and the second water outlet hole. The micro-nano bubble water can be switched between the micro-nano bubble water using mode and the micro-nano bubble water not using mode, and a user can select to use the micro-nano bubble water or not to use the micro-nano bubble water according to needs.

Description

Micro-nano bubble water generating device and control method thereof

Technical Field

The invention relates to the technical field of water heaters, in particular to a micro-nano bubble water generating device and a control method thereof.

Background

The micro-nano bubbles refer to bubbles with the diameter of 0.1-50 microns and have different physical and chemical properties from common bubbles. The micro-nano bubble has very small size, and the surface tension of the micro-nano bubble is very low, so that O2 molecules and water molecules are more easily combined. The micro-nano bubbles have small diameters, so that the micro-nano bubbles can easily permeate into pores and take away dirt in the pores; meanwhile, high-energy ultrasonic waves are generated when a large number of bubbles are dissolved and broken in water, and a large number of oxygen anions are generated. The bubble water has effects of sterilizing, enhancing immunity, improving allergic constitution, cleaning skin, moistening and invigorating dampness. Use micro-nano bubble water in the water heater field, when having loaded on the water heater micro-nano bubble water generating device, the user can not switch between using micro-nano bubble water and not using micro-nano bubble water according to its use needs, reduces user's use and experiences the sense.

Disclosure of Invention

The invention solves one of the problems in the prior related art to a certain extent, and therefore, one purpose of the invention is to provide a micro-nano bubble water generating device which can be switched between using micro-nano bubble water and not using micro-nano bubble water.

The above purpose is realized by the following technical scheme:

the utility model provides a micro-nano bubble water generating device, includes casing, rotary-cut structure, distributive pipe and baffle form in the casing and hold the chamber be equipped with water inlet, air inlet and delivery port on the casing, the baffle sets up and is being close to the one end of delivery port, the distributive pipe is intake end orientation the water inlet, the delivery end of distributive pipe with first apopore intercommunication that is equipped with on the baffle the delivery end department of distributive pipe still is equipped with the water valve, the rotatable setting of rotary-cut structure is in the distributive pipe is outside still be equipped with the second apopore on the baffle, the second apopore with hold the chamber intercommunication the water inlet with the air inlet passes through first apopore with the second apopore with the delivery port intercommunication.

As a further improvement of the present invention, the rotary cut structure comprises a spiral blade assembly, and the rotary cut structure has elasticity.

As a further improvement of the present invention, the spiral vane assembly includes a first spiral vane and a second spiral vane, the first spiral vane and the second spiral vane are disposed at an end near the water inlet, and the air inlet is disposed between the first spiral vane and the second spiral vane.

As a further improvement of the invention, a gap exists between the spiral blade assembly and the inner wall of the cavity, and the gap between the spiral blade assembly and the inner wall of the cavity is 0.5-2 cm.

As a further improvement of the invention, the space between the spiral blade assemblies is gradually reduced from top to bottom.

As a further improvement of the invention, a water inlet gap is formed between the water inlet end of the water diversion pipe and the water inlet, and the water inlet gap between the water inlet end of the water diversion pipe and the water inlet is 1-5 cm.

As a further improvement of the invention, the water inlet end of the water diversion pipe is arranged right below the water inlet, and the water outlet end of the water diversion pipe is arranged right below the water outlet end of the water diversion pipe.

As a further improvement of the invention, the peripheral edge of the baffle is connected with the inner wall of the cavity, and no gap exists between the peripheral edge of the baffle and the inner wall of the cavity.

As a further improvement of the invention, a water outlet cavity is formed between the baffle and the water outlet.

As a further improvement of the present invention, the second water outlet holes are arranged around the first water outlet hole, the second water outlet holes are circumferentially arranged on the baffle at intervals, and the aperture of the second water outlet hole is smaller than that of the first water outlet hole.

The invention aims to provide a control method of a micro-nano bubble water generating device, which can ensure the air inlet effect.

The above purpose is realized by the following technical scheme:

a control method of a micro-nano bubble water generating device comprises the following steps:

step S101, entering a bubble water function;

step S102, controlling an air booster pump to be started;

step S103, detecting the current water pressure P1 and the current air inlet pressure P2, and acquiring an air injection pressure difference delta P between the current water pressure P1 and the current air inlet pressure P2;

and step S104, controlling the gas injection pressure difference delta P to be larger than the preset pressure difference delta P0.

As a further improvement of the present invention, before step S101, the following steps are further included:

step S11, detecting whether the function of entering bubble water is selected;

if yes, go to step S101; if not, go to step S12;

and step S12, the air booster pump is closed, and the water valve is controlled to be opened.

As a further improvement of the present invention, in step S12, the air booster pump is turned off, and after the water valve is controlled to be opened, the method further includes the following steps:

step S13, heating the water according to a preset temperature and then discharging the water;

step S14, detecting whether to switch to the bubble water function;

if yes, go to step S101; if not, the process returns to step S13.

As a further improvement of the present invention, in step S103, the method of acquiring the injection gas pressure difference between the current water pressure P1 and the current intake pressure P2 is:

and delta P is P2-P1, wherein the air injection pressure difference is P1 is the current water pressure and P2 is the current advancing air pressure.

As a further improvement of the present invention, in step S104, the step of controlling the gas injection pressure difference Δ P to be greater than the preset pressure difference Δ P0 specifically includes:

step S401, detecting whether water flow or air inlet pressure changes;

if yes, go to step S402; if not, the process goes to step S403;

step S402, controlling and adjusting the forward air pressure P2 to control the gas injection pressure difference delta P to be larger than the preset pressure difference delta P0;

in step S403, the current air pressure P2 is kept constant.

As a further improvement of the present invention, in step S402, the method for controlling and adjusting the current forward air pressure P2 includes:

detecting an increase or decrease in water flow;

if the water flow is increased, controlling to increase the power of the air booster pump; if the water flow is reduced, the power of the air booster pump is reduced.

As a further improvement of the invention, the preset pressure difference delta P0 is 0.03-0.1 MPa.

Compared with the prior art, the invention at least comprises the following beneficial effects:

1. the invention provides a micro-nano bubble water generating device which can be switched between using micro-nano bubble water and not using micro-nano bubble water, and a user can select to use the micro-nano bubble water or not using the micro-nano bubble water according to the requirement.

2. The invention provides a control method of a micro-nano bubble water generating device, which controls a gas injection pressure difference delta P to be larger than a preset pressure difference delta P0, ensures a gas inlet effect and avoids the problem that gas is difficult to enter the micro-nano bubble water generating device due to overlarge water pressure caused by overlarge water flow.

Drawings

FIG. 1 is a schematic structural diagram of a micro-nano bubble water generating device in an embodiment;

FIG. 2 is a schematic cross-sectional view of a micro-nano bubble water generating device in an embodiment;

FIG. 3 is another schematic cross-sectional view of a micro-nano bubble water generating device in an embodiment;

fig. 4 is a flowchart of a control method of the micro-nano bubble water generating device in the embodiment.

Detailed Description

The present invention is illustrated by the following examples, but the present invention is not limited to these examples. Modifications to the embodiments of the invention or equivalent substitutions of parts of technical features without departing from the spirit of the invention are intended to be covered by the scope of the claims of the invention.

The first embodiment is as follows:

referring to fig. 1-3, a micro-nano bubble water generating device is shown, which comprises a shell 1, a rotary cutting structure 2, a water distribution pipe 3 and a baffle 4, a cavity 5 is formed in the shell 1, a water inlet 11, an air inlet 12 and a water outlet 13 are arranged on the shell 1, the baffle 4 is arranged at one end close to the water outlet 13, the water inlet end of the water diversion pipe 3 faces the water inlet 11, the water outlet end of the water distribution pipe 3 is communicated with a first water outlet hole 41 arranged on the baffle plate 4, a control valve 31 is arranged at the water outlet end of the water diversion pipe 3, the rotary cutting structure 2 is rotatably arranged outside the water diversion pipe 3, a second water outlet 42 is further formed in the baffle 4, the second water outlet 42 is communicated with the cavity 5, the water inlet 11 and the air inlet 12 are communicated with the water outlet 13 through the first water outlet hole 41 and the second water outlet hole 42.

The invention provides a micro-nano bubble water generating device which can be switched between using micro-nano bubble water and not using micro-nano bubble water, and a user can select to use the micro-nano bubble water or not using the micro-nano bubble water according to the requirement.

When the user chooses to use micro-nano bubble water, control valve 31 closes, and is preferred air inlet 12 department is equipped with the air booster pump, and control air booster pump opens, and gaseous enters into cavity 5 through air inlet 12 in, and when water inlet 11 entered into cavity 5 through water inlet 11, strikes rotary cut structure 2, drives rotary cut structure 2 and rotates, and rotary cut structure 2 rotates and drives fully mixing between gaseous and the liquid, and the micro-nano bubble water of production discharges from delivery port 13 through second apopore 42.

When the user chooses not to use the micro-nano bubble water, namely the user wants to use common water for bathing, the control valve 31 is controlled to be opened and the air booster pump is controlled to be closed. When the air enters the cavity 5 through the air inlet 12 and the water inlet 11 enters the cavity 5 through the water inlet 11, most of the water flows out from the water outlet 13 through the water diversion pipe 3 and the first water outlet 13, and part of the water flows out from the water outlet 13 through the cavity 5 and the second water outlet 42.

The rotary cutting structure 2 comprises a helical blade assembly 21, and the rotary cutting structure 2 has elasticity. When water flows into the cavity 5 from the water inlet 11, a tangential speed is given to the rotary cutting structure 2, and the rotary cutting structure 2 generates vibration under the impact of water due to the elasticity of the rotary cutting structure 2, wherein the vibration comprises the rotation and the up-and-down movement of the rotary cutting structure 2, so that gas and liquid can be sufficiently mixed.

In this embodiment, the water inlet 11 is disposed at the top of the chamber 5, and the water outlet 13 is disposed at the bottom of the chamber 5. The air inlet 12 is arranged on the side wall of the cavity 5 and is close to one end of the water inlet 11.

The helical blade assembly 21 comprises a plurality of helical blades, wherein the helical blades comprise a first helical blade 211 and a second helical blade 212, the first helical blade 211 and the second helical blade 212 are arranged at one end close to the water inlet 11, and the gas inlet 12 is arranged between the first helical blade 211 and the second helical blade 212, so that gas and liquid are fully mixed after gas is introduced. It is avoided that the gas inlet 12 is arranged between the spiral vane assembly 21 and the water inlet 11 such that gas enters the chamber 5 from the gas inlet 12 and then enters the water inlet 11. And the gas inlet 12 is far away from the first water outlet 41 and the second water outlet 42, so that the stroke path of the gas inlet 12 after entering the cavity 5 is prolonged, and sufficient mixing time is ensured before the gas and the liquid flow out from the first water outlet 41 and the second water outlet 42.

There is a clearance between the helical blade assembly 21 and the inner wall of the cavity 5, and the clearance between the helical blade assembly 21 and the inner wall of the cavity 5 is 0.5-2 cm. The gap between the spiral blade assembly 21 and the inner wall of the cavity 5 is reasonably set, so that the situation that the water and the gas are not fully mixed and flow out from the second water outlet 42 due to the fact that the gap between the spiral blade assembly 21 and the inner wall of the cavity 5 is too large is avoided; also avoid helical blade subassembly 21 with clearance undersize between the 5 inner walls of cavity causes helical blade constantly to assault 5 inner walls of cavity when vibrations under the rivers impact, causes too big noise, or to the wearing and tearing of 5 inner walls of cavity, leads to life to shorten.

The peripheral edge of baffle 4 with hold the intracavity wall and be connected, just there is not the clearance around the edge of baffle 4 with hold the intracavity wall. An outlet cavity 6 is formed between the baffle 4 and the water outlet 13. Micro-nano bubble water generated after the gas and the liquid are mixed enters the water outlet cavity 6 through the second water outlet 13 and then flows out through the water outlet 13.

The second apopore 42 sets up around first apopore 41, the second apopore 42 is in interval circumference sets up on baffle 4, just the aperture of second apopore 42 is less than the aperture of first apopore 41. The aperture of the second water outlet 42 is relatively small, so that micro-nano bubble water generated after gas and liquid are mixed is prevented from being discharged from the second water outlet 42 too fast. The first water outlet hole 41 is relatively large, so that when a user does not use micro-nano bubble water and uses ordinary water for bathing, a water outlet effect is ensured, and the problem of slow water outlet is avoided.

The distance between the spiral vane assemblies 21 is gradually reduced from top to bottom. The mixing effect between the gas and the liquid is ensured.

The water inlet end of the water diversion pipe 3 is arranged right below the water inlet 11, and the water outlet 13 is arranged right below the water outlet end of the water diversion pipe 3. Preferably, the diameter of the water diversion pipe 3 is larger than or equal to the diameter of the water inlet 11. When a user selects not to use micro-nano bubble water, water flow can directly enter the water distribution pipe 3 after entering the cavity 5 from the water inlet 11, flows out to the water outlet containing cavity 6 through the first water outlet 13 and is discharged from the water outlet 13, and the water body is ensured to flow out quickly.

A water inlet gap is formed between the water inlet end of the water diversion pipe 3 and the water inlet 11, and the water inlet gap between the water inlet end of the water diversion pipe 3 and the water inlet 11 is 1-5 cm. The reasonable clearance of intaking that sets up avoids the clearance of intaking too big, leads to when the user chooses not to use micro-nano bubble water, and the water can not flow out fast through distributive pipe 3, avoids the clearance undersize of intaking, leads to when the user chooses to use micro-nano bubble water function, and the water enters into the poor problem of the impact effect of cavity 5 interior pair rotary-cut blade.

The control valve 31 includes a water valve and a transmission bearing.

The water valve is electrically connected with the air booster pump, and the water valve is electrically connected with the air booster pump. The electrical connection includes a wired connection and a wireless connection.

Example two:

as shown in fig. 4, a method for controlling a micro-nano bubble water generating device, applied to a micro-nano drainage generating device in the first embodiment, includes the following steps:

step S101, entering a bubble water function;

step S102, controlling an air booster pump to be started;

step S103, detecting the current water pressure P1 and the current air inlet pressure P2, and acquiring an air injection pressure difference delta P between the current water pressure P1 and the current air inlet pressure P2;

and step S104, controlling the gas injection pressure difference delta P to be larger than the preset pressure difference delta P0.

In step S102, the air booster pump is provided at the air inlet.

In step S103, the current water pressure P1 changes according to the water flow rate, i.e., the larger the water flow rate, the larger the current water pressure P1.

In step S104, the predetermined differential pressure Δ P0 is 0.03-0.1 MPa.

The invention provides a control method of a micro-nano bubble water generating device, which controls a gas injection pressure difference delta P to be larger than a preset pressure difference delta P0, ensures a gas inlet effect and avoids the problem that gas is difficult to enter the micro-nano bubble water generating device due to overlarge water pressure caused by overlarge water flow.

The following steps are also included before step S101:

step S11, detecting whether the function of entering bubble water is selected;

if yes, go to step S101; if not, go to step S12;

and step S12, the air booster pump is closed, and the water valve is controlled to be opened.

The user can select to use the micro-nano bubble water or not according to the requirement, and the requirement of the user is guaranteed to be met.

In step S12, the method further includes the following steps after the air booster pump is turned off and the water valve is controlled to be opened:

step S13, heating the water according to a preset temperature and then discharging the water;

step S14, detecting whether to switch to the bubble water function;

if yes, go to step S101; if not, the process returns to step S13.

And if the user does not use the micro-nano bubble water for bathing, heating the water according to the preset temperature and then discharging the water. The function of entering the bubble water can be switched at any time in the bathing process of bathing without using the micro-nano bubble water by a user, so that the bathing effect is ensured, and the requirements of the user are met better.

In step S103, the method of acquiring the gas injection pressure difference Δ P0 between the current water pressure P1 and the current intake pressure P2 is:

and P2-P1, wherein the delta P0 is the gas injection pressure difference, P1 is the current water pressure, and P2 is the current advancing air pressure. In the using process, when the forward air pressure P2 is larger than the current water pressure P1, the gas can enter the micro-nano bubble water generating device.

Step S104, the step of controlling the gas injection pressure difference delta P to be larger than the preset pressure difference delta P0 specifically comprises the following steps:

step S401, detecting whether water flow changes;

if yes, go to step S402; if not, the process goes to step S403;

step S402, controlling and adjusting the forward air pressure P2 to control the gas injection pressure difference delta P to be larger than the preset pressure difference delta P0;

in step S403, the current air pressure P2 is kept constant.

When the user adjusts the inlet water flow rate to be larger or smaller, i.e. the inlet water flow rate changes, the air booster pump can be adjusted to adjust the inlet air pressure P2.

In step S402, the method for controlling and adjusting the current forward air pressure P2 includes:

detecting an increase or decrease in water flow;

if the water flow is increased, controlling to increase the power of the air booster pump; if the water flow is reduced, the power of the air booster pump is reduced.

The gas inlet effect is ensured, and the production of micro-nano bubble water is ensured.

The above preferred embodiments should be considered as examples of the embodiments of the present application, and technical deductions, substitutions, improvements and the like similar to, similar to or based on the embodiments of the present application should be considered as the protection scope of the present patent.

Claims (17)

1. The micro-nano bubble water generating device is characterized by comprising a shell (1), a rotary cutting structure (2), a water distribution pipe (3) and a baffle (4), wherein a cavity (5) is formed in the shell (1), a water inlet (11), an air inlet (12) and a water outlet (13) are arranged on the shell (1), an air booster pump is arranged at the position of the water outlet (13), the baffle (4) is arranged at one end close to the water outlet (13), the water inlet end of the water distribution pipe (3) faces towards the water inlet (11), the water outlet end of the water distribution pipe (3) is communicated with a first water outlet hole (41) formed in the baffle (4), a control valve is further arranged at the water outlet end of the water distribution pipe (3), the rotary cutting structure (2) is rotatably arranged outside the water distribution pipe (3), a second water outlet hole (42) is further formed in the baffle (4), the second water outlet hole (42) is communicated with the cavity (5), and the water inlet (11) and the air inlet (12) are communicated with the water outlet (13) through the first water outlet hole (41) and the second water outlet hole (42).

2. The micro-nano bubble water generating device according to claim 1, wherein the rotary-cut structure (2) comprises a spiral blade assembly (21), and the rotary-cut structure (2) has elasticity.

3. The micro-nano bubble water generating device according to claim 2, wherein the spiral blade assembly (21) comprises a first spiral blade (211) and a second spiral blade (212), the first spiral blade (211) and the second spiral blade (212) are disposed at one end close to the water inlet (11), and the air inlet (12) is disposed between the first spiral blade (211) and the second spiral blade (212).

4. The micro-nano bubble water generating device according to claim 2, wherein a gap exists between the spiral blade assembly (21) and the inner wall of the cavity (5), and the gap between the spiral blade assembly (21) and the inner wall of the cavity (5) is 0.5-2 cm.

5. The micro-nano bubble water generating device according to claim 2, wherein the distance between the spiral blade assemblies (21) is gradually reduced from top to bottom.

6. The micro-nano bubble water generating device according to claim 1, wherein a water inlet gap is formed between the water inlet end of the water dividing pipe (3) and the water inlet (11), and the water inlet gap between the water inlet end of the water dividing pipe (3) and the water inlet (11) is 1-5 cm.

7. The micro-nano bubble water generating device according to claim 1, wherein the water inlet end of the water dividing pipe (3) is arranged right below the water inlet (11), and the water outlet (13) is arranged right below the water outlet end of the water dividing pipe (3).

8. The micro-nano bubble water generating device according to claim 1, wherein the peripheral edge of the baffle (4) is connected with the inner wall of the cavity, and no gap exists between the peripheral edge of the baffle (4) and the inner wall of the cavity.

9. The micro-nano bubble water generating device according to claim 8, wherein a water outlet cavity (6) is formed between the baffle (4) and the water outlet (13).

10. The micro-nano bubble water generating device according to claim 8, wherein a second water outlet (42) is disposed around the first water outlet (41), the second water outlets (42) are circumferentially disposed on the baffle (4) at intervals, and the diameter of the second water outlet (42) is smaller than that of the first water outlet (41).

11. A control method of a micro-nano bubble water generating device, which is applied to the micro-nano bubble water generating device of any one of claims 1 to 10, is characterized by comprising the following steps:

step S101, entering a bubble water function;

step S102, controlling an air booster pump to be started;

step S103, detecting the current water pressure P1 and the current air inlet pressure P2, and acquiring an air injection pressure difference delta P between the current water pressure P1 and the current air inlet pressure P2;

and step S104, controlling the gas injection pressure difference delta P to be larger than the preset pressure difference delta P0.

12. The method for controlling a micro-nano bubble water generating device according to claim 11, further comprising the following steps before step S101:

step S11, detecting whether the function of entering bubble water is selected;

if yes, go to step S101; if not, go to step S12;

and step S12, the air booster pump is closed, and the water valve is controlled to be opened.

13. The method for controlling a micro-nano bubble water generating device according to claim 12, wherein in step S12, the air booster pump is turned off, and after the water valve is turned on, the method further comprises the following steps:

step S13, heating the water according to a preset temperature and then discharging the water;

step S14, detecting whether to switch to the bubble water function;

if yes, go to step S101; if not, the process returns to step S13.

14. The method for controlling a micro-nano bubble water generating device according to claim 11, wherein in step S103, the method for obtaining the gas injection pressure difference Δ P0 between the current water pressure P1 and the current intake pressure P2 comprises:

and P2-P1, wherein the delta P0 is the gas injection pressure difference, P1 is the current water pressure, and P2 is the current advancing air pressure.

15. The method for controlling a micro-nano bubble water generating device according to claim 11, wherein in step S104, the step of controlling the gas injection pressure difference Δ P to be greater than the preset pressure difference Δ P0 specifically comprises:

step S401, detecting whether water flow or air inlet pressure changes;

if yes, go to step S402; if not, the process goes to step S403;

step S402, controlling and adjusting the forward air pressure P2 to control the gas injection pressure difference delta P to be larger than the preset pressure difference delta P0;

in step S403, the current air pressure P2 is kept constant.

16. The method for controlling a micro-nano bubble water generating device according to claim 11, wherein in step S402, the method for controlling and adjusting the current forward air pressure P2 comprises:

detecting an increase or decrease in water flow;

if the water flow is increased, controlling to increase the power of the air booster pump; if the water flow is reduced, the power of the air booster pump is reduced.

17. The method for controlling a micro-nano bubble water generating device according to claim 11, wherein the preset pressure difference Δ P0 is 0.03-0.1 Mpa.

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